dict_tokenize.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
 */
 
/** Parse dictionary files
 *
 * @file src/lib/util/dict_tokenize.c
 *
 * @copyright 2019 The FreeRADIUS server project
 * @copyright 2024 Arran Cudbard-Bell (a.cudbardb@freeradius.org)
 */
RCSID("$Id: 88e49c2cc1d963a8a80f55f226964e15cc40eec6 $")
 
#include <freeradius-devel/radius/defs.h>
#include <freeradius-devel/util/conf.h>
#include <freeradius-devel/util/dict_fixup_priv.h>
#include <freeradius-devel/util/dict_priv.h>
#include <freeradius-devel/util/dict.h>
#include <freeradius-devel/util/file.h>
#include <freeradius-devel/util/rand.h>
#include <freeradius-devel/util/strerror.h>
#include <freeradius-devel/util/syserror.h>
#include <freeradius-devel/util/table.h>
#include <freeradius-devel/util/types.h>
#include <freeradius-devel/util/value.h>
 
#include <sys/stat.h>
 
/** Maximum number of arguments
 *
 * For any one keyword, this is the maxiumum number of arguments that can be passed.
 */
#define DICT_MAX_ARGV (8)
 
/** Maximum stack size
 *
 * This is the maximum number of nested BEGIN and $INCLUDE statements.
 */
#define DICT_MAX_STACK (32)
 
/** This represents explicit BEGIN/END frames pushed onto the stack
 *
 * These are flags to allow multiple nesting types to be passed to the search function.
 */
DIAG_OFF(attributes)
typedef enum CC_HINT(flag_enum) {
        NEST_NONE       = 0x00,
        NEST_ROOT       = 0x01,
        NEST_PROTOCOL   = 0x02,
        NEST_VENDOR     = 0x04,
        NEST_ATTRIBUTE  = 0x08
} dict_nest_t;
DIAG_ON(attributes)
 
static fr_table_num_sorted_t const dict_nest_table[] = {
        { L("ATTRIBUTE"),       NEST_ATTRIBUTE },
        { L("NONE"),            NEST_NONE },
        { L("PROTOCOL"),        NEST_PROTOCOL },
        { L("ROOT"),            NEST_ROOT },
        { L("VENDOR"),          NEST_VENDOR }
};
static size_t const dict_nest_table_len = NUM_ELEMENTS(dict_nest_table);
 
/** Parser context for dict_from_file
 *
 * Allows vendor and TLV context to persist across $INCLUDEs
 */
typedef struct {
        fr_dict_t               *dict;                  //!< The dictionary before the current BEGIN-PROTOCOL block.
        char                    *filename;              //!< name of the file we're reading
        int                     line;                   //!< line number of this file
        fr_dict_attr_t const    *da;                    //!< the da we care about
        dict_nest_t             nest;                   //!< for manual vs automatic begin / end things
        int                     member_num;             //!< structure member numbers
        fr_dict_attr_t const    *struct_is_closed;      //!< no more members are allowed
        ssize_t                 struct_size;            //!< size of the struct.
} dict_tokenize_frame_t;
 
struct dict_tokenize_ctx_s {
        fr_dict_t               *dict;                  //!< Protocol dictionary we're inserting attributes into.
 
        dict_tokenize_frame_t   stack[DICT_MAX_STACK];  //!< stack of attributes to track
        int                     stack_depth;            //!< points to the last used stack frame
 
        fr_dict_attr_t          *value_attr;            //!< Cache of last attribute to speed up value processing.
        fr_dict_attr_t const    *relative_attr;         //!< for ".82" instead of "1.2.3.82". only for parents of type "tlv"
        dict_fixup_ctx_t        fixup;
};
 
static int _dict_from_file(dict_tokenize_ctx_t *dctx,
                           char  const *dir_name, char const *filename,
                           char const *src_file, int src_line);
 
#define CURRENT_FRAME(_dctx)    (&(_dctx)->stack[(_dctx)->stack_depth])
#define CURRENT_DA(_dctx)       (CURRENT_FRAME(_dctx)->da)
#define CURRENT_FILENAME(_dctx) (CURRENT_FRAME(_dctx)->filename)
#define CURRENT_LINE(_dctx)     (CURRENT_FRAME(_dctx)->line)
 
#define ASSERT_CURRENT_NEST(_dctx, _nest) fr_assert_msg(CURRENT_FRAME(_dctx)->nest == (_nest), "Expected frame type %s, got %s", \
                                                fr_table_str_by_value(dict_nest_table, (_nest), "<INVALID>"), fr_table_str_by_value(dict_nest_table, CURRENT_FRAME(_dctx)->nest, "<INVALID>"))
 
void dict_dctx_debug(dict_tokenize_ctx_t *dctx)
{
        int i;
 
        for (i = 0; i <= dctx->stack_depth; i++) {
                FR_FAULT_LOG("[%d]: %s %s (%s): %s[%d]",
                             i,
                             fr_table_str_by_value(dict_nest_table, dctx->stack[i].nest, "<INVALID>"),
                             dctx->stack[i].da->name,
                             fr_type_to_str(dctx->stack[i].da->type),
                             dctx->stack[i].filename, dctx->stack[i].line);
        }
}
 
static dict_tokenize_frame_t const *dict_dctx_find_frame(dict_tokenize_ctx_t *dctx, dict_nest_t nest)
{
        int i;
 
        for (i = dctx->stack_depth; i >= 0; i--) {
                if (dctx->stack[i].nest & nest) return &dctx->stack[i];
        }
 
        return NULL;
}
 
static int dict_dctx_push(dict_tokenize_ctx_t *dctx, fr_dict_attr_t const *da, dict_nest_t nest)
{
        if ((dctx->stack_depth + 1) >= DICT_MAX_STACK) {
                fr_strerror_const_push("Attribute definitions are nested too deep.");
                return -1;
        }
 
        fr_assert(da != NULL);
 
        dctx->stack[++dctx->stack_depth] = (dict_tokenize_frame_t){
                .dict = dctx->stack[dctx->stack_depth - 1].dict,
                .da = da,
                .filename = dctx->stack[dctx->stack_depth - 1].filename,
                .line = dctx->stack[dctx->stack_depth - 1].line,
                .nest = nest
        };
 
        return 0;
}
 
/** Either updates the da in the current stack frame if 'nest' matches, or pushes a new frame of type 'nest'
 *
 * @param[in] dctx              Stack to push to.
 * @param[in] da                Attribute to push.
 * @param[in] nest              Frame type to push.
 * @return
 *      - 0 on success.
 *      - -1 on failure.
 */
static int CC_HINT(nonnull)
dict_dctx_push_or_update(dict_tokenize_ctx_t *dctx, fr_dict_attr_t const *da, dict_nest_t nest)
{
        if (dctx->stack[++dctx->stack_depth].nest == nest) {
                dctx->stack[dctx->stack_depth].filename = dctx->stack[dctx->stack_depth - 1].filename;
                dctx->stack[dctx->stack_depth].da = da;
                return 0;
        }
 
        return dict_dctx_push(dctx, da, nest);
}
 
 
/** Pop the current stack frame
 *
 * @param[in] dctx              Stack to pop from.
 * @preturn
 *      - Pointer to the current stack frame.
 *      - NULL, if we're already at the root.
 */
static dict_tokenize_frame_t const *dict_dctx_pop(dict_tokenize_ctx_t *dctx)
{
        if (dctx->stack_depth == 0) return NULL;
 
        return &dctx->stack[dctx->stack_depth--];
}
 
/** Unwind the entire stack, returning the root frame
 *
 * @param[in] dctx              Stack to unwind.
 * @return Pointer to the root frame.
 */
static dict_tokenize_frame_t const *dict_dctx_unwind(dict_tokenize_ctx_t *dctx)
{
        while ((dctx->stack_depth > 0) &&
               (dctx->stack[dctx->stack_depth].nest == NEST_NONE)) {
                dctx->stack_depth--;
        }
 
        return &dctx->stack[dctx->stack_depth];
}
 
/** Unwind the stack until it points to a particular type of stack frame
 *
 * @param[in] dctx              Stack to unwind.
 * @param[in] nest              Frame type to unwind to.
 * @return
 *      - Pointer to the frame matching nest
 *      - NULL, if we unwound the complete stack and didn't find the frame.
 */
static dict_tokenize_frame_t const *dict_dctx_unwind_until(dict_tokenize_ctx_t *dctx, dict_nest_t nest)
{
        while ((dctx->stack_depth > 0) &&
               !(dctx->stack[dctx->stack_depth].nest & nest)) {
                dctx->stack_depth--;
        }
 
        if (!(dctx->stack[dctx->stack_depth].nest & nest)) return NULL;
 
        return &dctx->stack[dctx->stack_depth];
}
 
/*
 *      String split routine.  Splits an input string IN PLACE
 *      into pieces, based on spaces.
 */
int fr_dict_str_to_argv(char *str, char **argv, int max_argc)
{
        int argc = 0;
 
        while (*str) {
                if (argc >= max_argc) break;
 
                /*
                 *      Chop out comments early.
                 */
                if (*str == '#') {
                        *str = '\0';
                        break;
                }
 
                while ((*str == ' ') ||
                       (*str == '\t') ||
                       (*str == '\r') ||
                       (*str == '\n'))
                        *(str++) = '\0';
 
                if (!*str) break;
 
                argv[argc] = str;
                argc++;
 
                while (*str &&
                       (*str != ' ') &&
                       (*str != '\t') &&
                       (*str != '\r') &&
                       (*str != '\n'))
                        str++;
        }
 
        return argc;
}
 
static int dict_read_sscanf_i(unsigned int *pvalue, char const *str)
{
        int unsigned ret = 0;
        int base = 10;
        static char const *tab = "0123456789";
 
        if ((str[0] == '0') &&
            ((str[1] == 'x') || (str[1] == 'X'))) {
                tab = "0123456789abcdef";
                base = 16;
 
                str += 2;
        }
 
        while (*str) {
                char const *c;
 
                if (*str == '.') break;
 
                c = memchr(tab, tolower((uint8_t)*str), base);
                if (!c) return 0;
 
                ret *= base;
                ret += (c - tab);
                str++;
        }
 
        *pvalue = ret;
        return 1;
}
 
/** Set a new root dictionary attribute
 *
 * @note Must only be called once per dictionary.
 *
 * @param[in] dict              to modify.
 * @param[in] name              of dictionary root.
 * @param[in] proto_number      The artificial (or IANA allocated) number for the protocol.
 *                              This is only used for
 * @return
 *      - 0 on success.
 *      - -1 on failure.
 */
static int dict_root_set(fr_dict_t *dict, char const *name, unsigned int proto_number)
{
        fr_dict_attr_t *da;
 
        fr_dict_attr_flags_t flags = {
                .is_root = 1,
                .type_size = 1,
                .length = 1
        };
 
        if (!fr_cond_assert(!dict->root)) {
                fr_strerror_const("Dictionary root already set");
                return -1;
        }
 
        da = dict_attr_alloc_root(dict->pool, dict, name, proto_number, &(dict_attr_args_t){ .flags = &flags });
        if (unlikely(!da)) return -1;
 
        dict->root = da;
        dict->root->dict = dict;
        DA_VERIFY(dict->root);
 
        return 0;
}
 
static int dict_process_type_field(dict_tokenize_ctx_t *dctx, char const *name, fr_dict_attr_t **da_p)
{
        char *p;
        fr_type_t type;
 
        /*
         *      Some types can have fixed length
         */
        p = strchr(name, '[');
        if (p) {
                char *q;
                unsigned int length;
 
                *p = '\0';
                q = strchr(p + 1, ']');
                if (!q) {
                        fr_strerror_printf("Invalid format for '%s[...]'", name);
                        return -1;
                }
 
                *q = '\0';
                if (q[1]) {
                        fr_strerror_const("length, if present, must end type field");
                        return -1;
                }
 
                if (!dict_read_sscanf_i(&length, p + 1)) {
                        fr_strerror_printf("Invalid length for '%s[...]'", name);
                        return -1;
                }
 
                /*
                 *      "length" has to fit into a uint8_t field.
                 */
                if ((length == 0) || (length > 255)) {
                        fr_strerror_printf("Invalid length for '%s[...]'", name);
                        return -1;
                }
 
                /*
                 *      Now that we have a length, check the data type.
                 */
                if (strcmp(name, "octets") == 0) {
                        type = FR_TYPE_OCTETS;
 
                } else if (strcmp(name, "string") == 0) {
                        type = FR_TYPE_STRING;
 
                } else if (strcmp(name, "struct") == 0) {
                        type = FR_TYPE_STRUCT;
 
                } else if (strcmp(name, "bit") == 0) {
                        if (dctx->stack[dctx->stack_depth].da->type != FR_TYPE_STRUCT) {
                                fr_strerror_const("Bit fields can only be used inside of a STRUCT");
                                return -1;
                        }
 
                        (*da_p)->flags.extra = 1;
                        (*da_p)->flags.subtype = FLAG_BIT_FIELD;
 
                        if (length == 1) {
                                type = FR_TYPE_BOOL;
                        } else if (length <= 8) {
                                type = FR_TYPE_UINT8;
                        } else if (length <= 16) {
                                type = FR_TYPE_UINT16;
                        } else if (length <= 32) {
                                type = FR_TYPE_UINT32;
                        } else if (length <= 56) { /* for laziness in encode / decode */
                                type = FR_TYPE_UINT64;
                        } else {
                                fr_strerror_const("Invalid length for bit field");
                                return -1;
                        }
 
                        /*
                         *      Cache where on a byte boundary this
                         *      bit field ends.  We could have the
                         *      validation function loop through all
                         *      previous siblings, but that's
                         *      annoying.
                         */
                        (*da_p)->flags.flag_byte_offset = length;
 
                } else {
                        fr_strerror_const("Only 'octets', 'string', 'struct', or 'bit' types can have a 'length' parameter");
                        return -1;
                }
 
                (*da_p)->flags.is_known_width = true;
                (*da_p)->flags.length = length;
                return dict_attr_type_init(da_p, type);
        }
 
        /*
         *      find the type of the attribute.
         */
        type = fr_type_from_str(name);
        if (fr_type_is_null(type)) {
                if (!dctx->dict->proto->attr.type_parse) {
                        fr_strerror_printf("Unknown data type '%s'", name);
                        return -1;
                }
 
                if (!dctx->dict->proto->attr.type_parse(&type, da_p, name)) {
                        return -1;
                }
 
                fr_assert(!fr_type_is_null(type));
        }
 
        return dict_attr_type_init(da_p, type);
}
 
/** Define a flag setting function, which sets one bit in a fr_dict_attr_flags_t
 *
 * This is here, because AFAIK there's no completely portable way to get the bit
 * offset of a bit field in a structure.
 */
#define FLAG_FUNC(_name) \
static int dict_flag_##_name(fr_dict_attr_t **da_p, UNUSED char const *value, UNUSED fr_dict_flag_parser_rule_t const *rules)\
{ \
        (*da_p)->flags._name = 1; \
        return 0; \
}
 
FLAG_FUNC(array)
 
static int dict_flag_clone(fr_dict_attr_t **da_p, char const *value, UNUSED fr_dict_flag_parser_rule_t const *rules)
{
        if (((*da_p)->type != FR_TYPE_TLV) && ((*da_p)->type != FR_TYPE_STRUCT)) {
                fr_strerror_const("'clone=...' references can only be used for 'tlv' and 'struct' types");
                return -1;
        }
 
        /*
         *      Allow cloning of any types, so long as
         *      the types are the same.  We do the checks later.
         */
        if (unlikely(dict_attr_ref_aunresolved(da_p, value, FR_DICT_ATTR_REF_CLONE) < 0)) return -1;
 
        return 0;
}
 
FLAG_FUNC(counter)
 
static int dict_flag_enum(fr_dict_attr_t **da_p, char const *value, UNUSED fr_dict_flag_parser_rule_t const *rule)
{
        /*
         *      Allow enum=... as a synonym for
         *      "clone".  We check the sources and not
         *      the targets, because that's easier.
         *
         *      Plus, ENUMs are really just normal attributes
         *      in disguise.
         */
        if (!fr_type_is_leaf((*da_p)->type)) {
                fr_strerror_const("'enum=...' references cannot be used for structural types");
                return -1;
        }
 
        if (unlikely(dict_attr_ref_aunresolved(da_p, value, FR_DICT_ATTR_REF_ENUM) < 0)) return -1;
 
        return 0;
}
 
FLAG_FUNC(internal)
 
static int dict_flag_key(fr_dict_attr_t **da_p, UNUSED char const *value, UNUSED fr_dict_flag_parser_rule_t const *rule)
{
        fr_dict_attr_t *da = *da_p;
 
        if ((da->type != FR_TYPE_UINT8) && (da->type != FR_TYPE_UINT16) && (da->type != FR_TYPE_UINT32)) {
                fr_strerror_const("The 'key' flag can only be used for attributes of type 'uint8', 'uint16', or 'uint32'");
                return -1;
        }
 
        if (da->flags.extra) {
                fr_strerror_const("Bit fields cannot be key fields");
                return -1;
        }
 
        da->flags.extra = 1;
        da->flags.subtype = FLAG_KEY_FIELD;
 
        return 0;
}
 
static int dict_flag_length(fr_dict_attr_t **da_p, char const *value, UNUSED fr_dict_flag_parser_rule_t const *rule)
{
        fr_dict_attr_t *da = *da_p;
 
        if (strcmp(value, "uint8") == 0) {
                da->flags.extra = 1;
                da->flags.subtype = FLAG_LENGTH_UINT8;
 
        } else if (strcmp(value, "uint16") == 0) {
                da->flags.extra = 1;
                da->flags.subtype = FLAG_LENGTH_UINT16;
 
        } else {
                fr_strerror_const("Invalid value given for the 'length' flag");
                return -1;
        }
        da->flags.type_size = 0;
 
        return 0;
}
 
static int dict_flag_offset(fr_dict_attr_t **da_p, char const *value, UNUSED fr_dict_flag_parser_rule_t const *rule)
{
        fr_dict_attr_t *da = *da_p;
        int offset;
 
        if (da->type != FR_TYPE_STRUCT) {
                fr_strerror_const("The 'offset' flag can only be used with data type 'struct'");
                return -1;
        }
 
        if (!da->flags.extra || (!(da->flags.subtype == FLAG_LENGTH_UINT8) || (da->flags.subtype == FLAG_LENGTH_UINT16))) {
                fr_strerror_const("The 'offset' flag can only be used in combination with 'length=uint8' or 'length=uint16'");
                return -1;
        }
 
        offset = atoi(value);
        if ((offset <= 0) || (offset > 255)) {
                fr_strerror_const("The 'offset' value must be between 1..255");
                return -1;
        }
        da->flags.type_size = offset;
 
        return 0;
}
 
static int dict_flag_precision(fr_dict_attr_t **da_p, char const *value, UNUSED fr_dict_flag_parser_rule_t const *rule)
{
        fr_dict_attr_t *da = *da_p;
        int precision;
 
        switch (da->type) {
        case FR_TYPE_DATE:
        case FR_TYPE_TIME_DELTA:
                break;
 
        default:
                fr_strerror_const("The 'precision' flag can only be used with data types 'date' or 'time'");
                return -1;
        }
 
        precision = fr_table_value_by_str(fr_time_precision_table, value, -1);
        if (precision < 0) {
                fr_strerror_printf("Unknown %s precision '%s'", fr_type_to_str(da->type), value);
                return -1;
        }
        da->flags.flag_time_res = precision;
 
        return 0;
}
 
static int dict_flag_ref(fr_dict_attr_t **da_p, char const *value, UNUSED fr_dict_flag_parser_rule_t const *rule)
{
        fr_dict_attr_t *da = *da_p;
 
        if (da->flags.extra) {
                fr_strerror_const("Cannot use 'ref' with other flags");
                return -1;
        }
 
        if (da->type != FR_TYPE_GROUP) {
                fr_strerror_printf("The 'ref' flag cannot be used for type '%s'",
                                        fr_type_to_str(da->type));
                return -1;
        }
 
        if (unlikely(dict_attr_ref_aunresolved(da_p, value, FR_DICT_ATTR_REF_ALIAS) < 0)) return -1;
 
        return 0;
}
 
static int dict_flag_secret(fr_dict_attr_t **da_p, UNUSED char const *value, UNUSED fr_dict_flag_parser_rule_t const *rule)
{
        fr_dict_attr_t *da = *da_p;
 
        da->flags.secret = 1;
 
        if ((da->type != FR_TYPE_STRING) && (da->type != FR_TYPE_OCTETS)) {
                fr_strerror_const("The 'secret' flag can only be used with data types 'string' or 'octets'");
                return -1;
        }
 
        return 0;
}
 
static int dict_flag_subtype(fr_dict_attr_t **da_p, char const *value, UNUSED fr_dict_flag_parser_rule_t const *rule)
{
        fr_dict_attr_t *da = *da_p;
        fr_type_t subtype;
 
        switch (da->type) {
        case FR_TYPE_DATE:
        case FR_TYPE_TIME_DELTA:
                break;
 
        default:
                fr_strerror_const("The 'subtype' flag can only be used with data types 'date' or 'time'");
                return -1;
        }
 
        subtype = fr_type_from_str(value);
        if (fr_type_is_null(subtype)) {
        unknown_type:
                fr_strerror_printf("Unknown or unsupported %s type '%s'",
                                   fr_type_to_str(subtype),
                                   value);
                return -1;
        }
 
        switch (subtype) {
                default:
                        goto unknown_type;
 
        case FR_TYPE_INT16:
                if (da->type == FR_TYPE_DATE) goto unknown_type;
                da->flags.length = 2;
                break;
 
        case FR_TYPE_UINT16:
                da->flags.is_unsigned = true;
                da->flags.length = 2;
                break;
 
        case FR_TYPE_INT32:
                if (da->type == FR_TYPE_DATE) goto unknown_type;
                da->flags.length = 4;
                break;
 
        case FR_TYPE_UINT32:
                da->flags.is_unsigned = true;
                da->flags.length = 4;
                break;
 
        case FR_TYPE_INT64:
                if (da->type == FR_TYPE_DATE) goto unknown_type;
                da->flags.length = 8;
                break;
 
        case FR_TYPE_UINT64:
                da->flags.is_unsigned = true;
                da->flags.length = 8;
                break;
        }
 
        return 0;
}
 
/** A lookup function for dictionary attribute flags
 *
 */
static TABLE_TYPE_NAME_FUNC_RPTR(table_sorted_value_by_str, fr_dict_flag_parser_t const *,
                                 fr_dict_attr_flag_to_parser, fr_dict_flag_parser_rule_t const *, fr_dict_flag_parser_rule_t const *)
 
static int CC_HINT(nonnull) dict_process_flag_field(dict_tokenize_ctx_t *dctx, char *name, fr_dict_attr_t **da_p)
{
        static fr_dict_flag_parser_t dict_common_flags[] = {
                { L("array"),           { .func = dict_flag_array } },
                { L("clone"),           { .func = dict_flag_clone, .needs_value = true } },
                { L("counter"),         { .func = dict_flag_counter } },
                { L("enum"),            { .func = dict_flag_enum, .needs_value = true } },
                { L("internal"),        { .func = dict_flag_internal } },
                { L("key"),             { .func = dict_flag_key } },
                { L("length"),          { .func = dict_flag_length, .needs_value = true } },
                { L("offset"),          { .func = dict_flag_offset, .needs_value = true } },
                { L("precision"),       { .func = dict_flag_precision, .needs_value = true } },
                { L("ref"),             { .func = dict_flag_ref, .needs_value = true } },
                { L("secret"),          { .func = dict_flag_secret } },
                { L("subtype"),         { .func = dict_flag_subtype, .needs_value = true } }
        };
        static size_t dict_common_flags_len = NUM_ELEMENTS(dict_common_flags);
 
        char *p, *next = NULL;
 
        if ((*da_p)->type == FR_TYPE_NULL) {
                fr_strerror_const("Type must be specified before parsing flags");
                return -1;
        }
 
        for (p = name; p && *p != '\0' ; p = next) {
                char *key, *value;
                fr_dict_flag_parser_rule_t const *parser;
 
                key = p;
 
                /*
                 *      Search for the first '=' or ','
                 */
                for (next = p + 1; *next && (*next != '=') && (*next != ','); next++) {
                        /* do nothing */
                }
 
                /*
                 *      We have a value, zero out the '=' and point to the value.
                 */
                if (*next == '=') {
                        *(next++) = '\0';
                        value = next;
 
                        if (!*value || (*value == ',')) {
                                fr_strerror_printf("Missing value after '%s='", key);
                                return -1;
                        }
                } else {
                        value = NULL;
                }
 
                /*
                 *      Skip any trailing text in the value.
                 */
                for (/* nothing */; *next; next++) {
                        if (*next == ',') {
                                *(next++) = '\0';
                                break;
                        }
                }
 
                /*
                 *      Search the protocol table, then the main table.
                 *      This allows protocols to overload common flags.
                 */
                if (!((dctx->dict->proto->attr.flags.table &&
                       fr_dict_attr_flag_to_parser(&parser, dctx->dict->proto->attr.flags.table,
                                                   dctx->dict->proto->attr.flags.table_len, key, NULL)) ||
                       fr_dict_attr_flag_to_parser(&parser, dict_common_flags, dict_common_flags_len, key, NULL))) {
                        fr_strerror_printf("Unknown flag '%s'", key);
                        return -1;
                }
 
                if (parser->needs_value && !value) {
                        fr_strerror_printf("Flag '%s' requires a value", key);
                        return -1;
                }
 
                if (unlikely(parser->func(da_p, value, parser) < 0)) return -1;
        }
 
        /*
         *      Don't check the flags field for validity via
         *      dict_attr_flags_valid().  It may be updated by various
         *      protocol-specific callback functions.  And,
         *      fr_dict_attr_add() calls dict_attr_flags_valid() anyways.
         */
 
        return 0;
}
 
static int dict_finalise(dict_tokenize_ctx_t *dctx)
{
        if (dict_fixup_apply(&dctx->fixup) < 0) return -1;
 
        dctx->value_attr = NULL;
        dctx->relative_attr = NULL;
 
        return 0;
}
 
static inline CC_HINT(always_inline)
void dict_attr_location_set(dict_tokenize_ctx_t *dctx, fr_dict_attr_t *da)
{
        da->filename = dctx->stack[dctx->stack_depth].filename;
        da->line = dctx->stack[dctx->stack_depth].line;
}
 
/** Add an attribute to the dictionary, or add it to a list of attributes to clone later
 *
 * @param[in] fixup     context to add an entry to (if needed).
 * @param[in] da_p      to either add, or create a fixup for.
 * @return
 *      - 0 on success, and an attribute was added.
 *      - 1 on success, and a deferred entry was added.
 *      - -1 on failure.
 */
static int dict_attr_add_or_fixup(dict_fixup_ctx_t *fixup, fr_dict_attr_t **da_p)
{
        fr_dict_attr_ext_ref_t  *ref;
        fr_dict_attr_t *da = *da_p;
        int ret = 0;
 
        /*
         *      Check for any references associated with the attribute,
         *      if they're unresolved, then add fixups.
         *
         *      We do this now, as we know the attribute memory chunk
         *      is stable, and we can safely add the fixups.
         */
        ref = fr_dict_attr_ext(*da_p, FR_DICT_ATTR_EXT_REF);
        if (ref && fr_dict_attr_ref_is_unresolved(ref->type)) {
                switch (fr_dict_attr_ref_type(ref->type)) {
                case FR_DICT_ATTR_REF_ALIAS:
                        if (fr_dict_attr_add_initialised(da) < 0) {
                        error:
                                talloc_free(da);
                                *da_p = NULL;
                                return -1;
                        }
 
                        if (dict_fixup_group_enqueue(fixup, da, ref->unresolved) < 0) return -1;
                        break;
 
                case FR_DICT_ATTR_REF_ENUM:
                        if (fr_dict_attr_add_initialised(da) < 0) goto error;
 
                        if (dict_fixup_clone_enum_enqueue(fixup, da, ref->unresolved) < 0) return -1;
                        break;
 
                case FR_DICT_ATTR_REF_CLONE:
                {
                        /*
                         *      See if we can immediately apply the clone
                         */
                        fr_dict_attr_t const *src = dict_protocol_reference(da->parent, ref->unresolved, true);
                        if (src) {
                                if (dict_fixup_clone(da_p, src) < 0) return -1;
                                break;
                        }
 
                        if (dict_fixup_clone_enqueue(fixup, da, ref->unresolved) < 0) return -1;
                        ret = 1;
                }
                        break;
 
                default:
                        fr_strerror_const("Unknown reference type");
                        return -1;
                }
        } else {
                if (fr_dict_attr_add_initialised(da) < 0) goto error;
        }
 
        return ret;
}
 
/** Check if this definition is a duplicate, and if it is, whether we should skip it error out
 *
 * @return
 *      - 1 if this is not a duplicate.
 *      - 0 if this is a duplicate, and we should ignore the definition.
 *      - -1 if this is a duplicate, and we should error out.
 */
static int dict_attr_allow_dup(fr_dict_attr_t const *da)
{
        fr_dict_attr_t const *dup_name = NULL;
        fr_dict_attr_t const *dup_num = NULL;
        fr_dict_attr_t const *found;
 
        /*
         *      Search in the parent for a duplicate by name and then by num
         */
        if (!da->parent) return 1;      /* no parent no conflicts possible */
 
        dup_name = fr_dict_attr_by_name(NULL, da->parent, da->name);
        if (da->flags.name_only) dup_num = fr_dict_attr_child_by_num(da->parent, da->attr);
 
        /*
         *      Not a duplicate...
         */
        if (!dup_name && !dup_num) return 1;
 
        found = dup_name ? dup_name : dup_num;
 
        switch (da->type) {
        /*
         *      For certain STRUCTURAL types, we allow strict duplicates
         *      as if the user wants to add extra children in the custom
         *      dictionary, or wants to avoid ordering issues between
         *      multiple dictionaries, we need to support this.
         */
        case FR_TYPE_VSA:
        case FR_TYPE_VENDOR:
        case FR_TYPE_TLV:
                if (fr_dict_attr_cmp_fields(da, found) == 0) return -1;
                break;
 
        default:
                break;
        }
 
        if (dup_name) {
                fr_strerror_printf("Duplicate attribute name '%s' in namespace '%s'.  Originally defined %s[%d]",
                                   da->name, da->parent->name, dup_name->filename, dup_name->line);
                return 0;
        }
 
        fr_strerror_printf("Duplicate attribute number %u in parent '%s'.  Originally defined %s[%d]",
                                da->attr, da->parent->name, dup_num->filename, dup_num->line);
        return 0;
}
 
static int dict_set_value_attr(dict_tokenize_ctx_t *dctx, fr_dict_attr_t *da)
{
        /*
         *      Adding an attribute of type 'struct' is an implicit
         *      BEGIN-STRUCT.
         */
        if (da->type == FR_TYPE_STRUCT) {
                if (dict_dctx_push(dctx, da, 0) < 0) return -1;
                dctx->value_attr = NULL;
        } else if (fr_type_is_leaf(da->type)) {
                memcpy(&dctx->value_attr, &da, sizeof(da));
        } else {
                dctx->value_attr = NULL;
        }
 
        return 0;
}
 
static int dict_read_process_common(dict_tokenize_ctx_t *dctx, fr_dict_attr_t **da_p,
                                    char const *name,
                                    char const *type_name, char *flag_name,
                                    fr_dict_attr_flags_t const *base_flags)
{
        fr_dict_attr_t *da;
 
        /*
         *      Dictionaries need to have real names, not shitty ones.
         */
        if (strncmp(name, "Attr-", 5) == 0) {
                fr_strerror_const("Invalid name");
                return -1;
        }
 
        /*
         *      Allocate the attribute here, and then fill in the fields
         *      as we start parsing the various elements of the definition.
         */
        da = dict_attr_alloc_null(dctx->dict->pool, dctx->dict->proto);
        if (unlikely(da == NULL)) return -1;
        dict_attr_location_set(dctx, da);
        da->dict = dctx->dict;
 
        /*
         *      Set the attribute flags from the base flags.
         */
        memcpy(&da->flags, base_flags, sizeof(da->flags));
 
        /*
         *      Set the base type of the attribute.
         */
        if (dict_process_type_field(dctx, type_name, &da) < 0) {
        error:
                talloc_free(da);
                return -1;
        }
 
        /*
         *      Parse optional flags.  We pass in the partially allocated
         *      attribute so that flags can be set directly.
         *
         *      Where flags contain variable length fields, this is
         *      significantly easier than populating a temporary struct.
         */
        if (flag_name) if (dict_process_flag_field(dctx, flag_name, &da) < 0) goto error;
 
        *da_p = da;
        return 0;
}
 
/*
 *      Process the $INCLUDE command
 */
static int dict_read_process_include(dict_tokenize_ctx_t *dctx, char **argv, int argc, char const *dir)
{
        int rcode;
        int stack_depth = dctx->stack_depth;
        char *fn = CURRENT_FILENAME(dctx);
        int line = CURRENT_LINE(dctx);
 
        /*
         *      Allow "$INCLUDE" or "$INCLUDE-", but
         *      not anything else.
         */
        if ((argv[0][8] != '\0') && ((argv[0][8] != '-') || (argv[0][9] != '\0'))) {
                fr_strerror_printf("Invalid keyword '%s'", argv[0]);
                return -1;
        }
 
        if (argc != 2) {
                fr_strerror_printf("Unexpected text after $INCLUDE at %s[%d]", fr_cwd_strip(fn), line);
                return -1;
        }
 
        /*
         *      Allow limited macro capability, so
         *      people don't have to remember where
         *      the root dictionaries are located.
         */
        if (strncmp(argv[1], "${dictdir}/", 11) != 0) {
                rcode = _dict_from_file(dctx, dir, argv[1], fn, line);
        } else {
                rcode = _dict_from_file(dctx, fr_dict_global_ctx_dir(), argv[1] + 11, fn, line);
        }
 
        if ((rcode == -2) && (argv[0][8] == '-')) {
                fr_strerror_clear(); /* delete all errors */
                return 0;
        }
 
        if (rcode < 0) {
                fr_strerror_printf_push("from $INCLUDE at %s[%d]", fr_cwd_strip(fn), line);
                return -1;
        }
 
        if (dctx->stack_depth < stack_depth) {
                fr_strerror_printf_push("unexpected END-??? in $INCLUDE at %s[%d]",
                                        fr_cwd_strip(fn), line);
                return -1;
        }
 
        while (dctx->stack_depth > stack_depth) {
                if (dctx->stack[dctx->stack_depth].nest == NEST_NONE) {
                        dctx->stack_depth--;
                        continue;
                }
 
                fr_strerror_printf_push("BEGIN-??? without END-... in file $INCLUDEd from %s[%d]",
                                        fr_cwd_strip(fn), line);
                return -1;
        }
 
        /*
         *      Reset the filename.
         */
        dctx->stack[dctx->stack_depth].filename = fn;
 
        return 0;
}
 
static int dict_read_parse_format(char const *format, int *ptype, int *plength, bool *pcontinuation)
{
        char const *p;
        int type, length;
        bool continuation = false;
 
        if (strncasecmp(format, "format=", 7) != 0) {
                fr_strerror_printf("Invalid format for VENDOR.  Expected 'format=', got '%s'",
                                   format);
                return -1;
        }
 
        p = format + 7;
        if ((strlen(p) < 3) ||
            !isdigit((uint8_t)p[0]) ||
            (p[1] != ',') ||
            !isdigit((uint8_t)p[2]) ||
            (p[3] && (p[3] != ','))) {
                fr_strerror_printf("Invalid format for VENDOR.  Expected text like '1,1', got '%s'",
                                   p);
                return -1;
        }
 
        type = (int)(p[0] - '0');
        length = (int)(p[2] - '0');
 
        if ((type != 1) && (type != 2) && (type != 4)) {
                fr_strerror_printf("Invalid type value %d for VENDOR", type);
                return -1;
        }
 
        if ((length != 0) && (length != 1) && (length != 2)) {
                fr_strerror_printf("Invalid length value %d for VENDOR", length);
                return -1;
        }
 
        if (p[3] == ',') {
                if (!p[4]) {
                        fr_strerror_printf("Invalid format for VENDOR.  Expected text like '1,1', got '%s'",
                                           p);
                        return -1;
                }
 
                if ((p[4] != 'c') ||
                    (p[5] != '\0')) {
                        fr_strerror_printf("Invalid format for VENDOR.  Expected text like '1,1', got '%s'",
                                           p);
                        return -1;
                }
                continuation = true;
 
                if ((type != 1) || (length != 1)) {
                        fr_strerror_const("Only VSAs with 'format=1,1' can have continuations");
                        return -1;
                }
        }
 
        *ptype = type;
        *plength = length;
        *pcontinuation = continuation;
        return 0;
}
 
/*
 *      Process the ALIAS command
 *
 *      ALIAS name ref
 *
 *      Creates an attribute "name" in the root namespace of the current
 *      dictionary, which is a pointer to "ref".
 */
static int dict_read_process_alias(dict_tokenize_ctx_t *dctx, char **argv, int argc, UNUSED fr_dict_attr_flags_t *base_flags)
{
        fr_dict_attr_t const    *da;
        fr_dict_attr_t const    *parent = dctx->stack[dctx->stack_depth].da;
        fr_dict_attr_t const    *ref_namespace;
 
        if (argc != 2) {
                fr_strerror_const("Invalid ALIAS syntax");
                return -1;
        }
 
        /*
         *      Dictionaries need to have real names, not shitty ones.
         */
        if (strncmp(argv[0], "Attr-", 5) == 0) {
                fr_strerror_const("Invalid ALIAS name");
                return -1;
        }
 
        /*
         *      Relative refs get resolved from the current namespace.
         */
        if (argv[1][0] == '.') {
                ref_namespace = parent;
        /*
         *      No dot, so we're looking in the root namespace.
         */
        } else {
                ref_namespace = dctx->dict->root;
        }
 
        /*
         *      The <ref> can be a name.
         */
        da = fr_dict_attr_by_oid(NULL, ref_namespace, argv[1]);
        if (!da) {
                /*
                 *      If we can't find it now, the file
                 *      containing the ALIASes may have
                 *      been allowed before the ALIASed
                 *      attributes.
                 */
                return dict_fixup_alias_enqueue(&dctx->fixup, CURRENT_FRAME(dctx)->filename, CURRENT_FRAME(dctx)->line,
                                        fr_dict_attr_unconst(parent), argv[0],
                                        fr_dict_attr_unconst(ref_namespace), argv[1]);
        }
 
        return dict_attr_alias_add(fr_dict_attr_unconst(parent), argv[0], da);
}
 
/*
 *      Process the ATTRIBUTE command
 */
static int dict_read_process_attribute(dict_tokenize_ctx_t *dctx, char **argv, int argc, fr_dict_attr_flags_t *base_flags)
{
        bool                    set_relative_attr;
 
        ssize_t                 slen;
        unsigned int            attr;
 
        fr_dict_attr_t const    *parent;
        fr_dict_attr_t          *da;
 
        if ((argc < 3) || (argc > 4)) {
                fr_strerror_const("Invalid ATTRIBUTE syntax");
                return -1;
        }
 
        if (dict_read_process_common(dctx, &da, argv[0], argv[2],
                                     (argc > 3) ? argv[3] : NULL, base_flags) < 0) {
                return -1;
        }
 
        if (da->flags.extra && (da->flags.subtype == FLAG_BIT_FIELD)) {
                fr_strerror_const("Bit fields can only be defined as a MEMBER of a STRUCT");
                goto error;
        }
 
        /*
         *      A non-relative ATTRIBUTE definition means that it is
         *      in the context of the previous BEGIN-FOO.  So we
         *      unwind the stack to match.
         */
        if (argv[1][0] != '.') {
                parent = dict_dctx_unwind(dctx)->da;
 
                /*
                 *      Allow '0xff00' as attribute numbers, but only
                 *      if there is no OID component.
                 */
                if (strchr(argv[1], '.') == 0) {
                        if (!dict_read_sscanf_i(&attr, argv[1])) {
                                fr_strerror_const("Invalid ATTRIBUTE number");
                                goto error;
                        }
 
                } else {
                        slen = fr_dict_attr_by_oid_legacy(dctx->dict, &parent, &attr, argv[1]);
                        if (slen <= 0) goto error;
                }
 
                /*
                 *      We allow relative attributes only for TLVs.
                 */
                set_relative_attr = (da->type == FR_TYPE_TLV);
 
        } else {
                if (!dctx->relative_attr) {
                        fr_strerror_const("Unknown parent for partial OID");
                        goto error;
                }
 
                parent = dctx->relative_attr;
 
                slen = fr_dict_attr_by_oid_legacy(dctx->dict, &parent, &attr, argv[1]);
                if (slen <= 0) goto error;
 
                set_relative_attr = false;
        }
 
        /*
         *      Record the attribute number
         */
        if (unlikely(dict_attr_num_init(da, attr) < 0)) {
        error:
                talloc_free(da);
                return -1;
        }
 
        /*
         *      Members of a 'struct' MUST use MEMBER, not ATTRIBUTE.
         */
        if (parent->type == FR_TYPE_STRUCT) {
                fr_strerror_printf("Member %s of ATTRIBUTE %s type 'struct' MUST use the \"MEMBER\" keyword",
                                   argv[0], parent->name);
                goto error;
        }
 
        if (!fr_cond_assert(parent)) goto error;        /* Should have provided us with a parent */
 
        /*
         *      Set the parent we just determined...
         */
        if (unlikely(dict_attr_parent_init(&da, parent) < 0)) goto error;
 
#ifdef WITH_DICTIONARY_WARNINGS
        /*
         *      Hack to help us discover which vendors have illegal
         *      attributes.
         */
        if (!vendor && (attr < 256) &&
            !strstr(fn, "rfc") && !strstr(fn, "illegal")) {
                fprintf(stderr, "WARNING: Illegal attribute %s in %s\n",
                        argv[0], fn);
        }
#endif
 
#ifdef STATIC_ANALYZER
        if (!dctx->dict) return -1;
#endif
 
        /*
         *      Set the attribute name
         */
        if (unlikely(dict_attr_finalise(&da, argv[0]) < 0)) goto error;
 
        /*
         *      Check to see if this is a duplicate attribute
         *      and whether we should ignore it or error out...
         */
        switch (dict_attr_allow_dup(da)) {
        case 1:
                break;
 
        case 0:
                talloc_free(da);
                return 0;
 
        default:
                goto error;
        }
 
        /*
         *      Add the attribute we allocated earlier
         */
        switch (dict_attr_add_or_fixup(&dctx->fixup, &da)) {
        default:
                goto error;
 
        /* New attribute, fixup stack */
        case 0:
                /*
                 *      Dynamically define where VSAs go.  Note that we CANNOT
                 *      define VSAs until we define an attribute of type VSA!
                 */
                if (da->type == FR_TYPE_VSA) {
                        if (parent->flags.is_root) dctx->dict->vsa_parent = attr;
 
                        if (dict_fixup_vsa_enqueue(&dctx->fixup, UNCONST(fr_dict_attr_t *, da)) < 0) {
                                return -1;      /* Leaves attr added */
                        }
                }
 
                /*
                 *      Adding an attribute of type 'struct' is an implicit
                 *      BEGIN-STRUCT.
                 */
                if (da->type == FR_TYPE_STRUCT) {
                        if (dict_dctx_push(dctx, da, 0) < 0) return -1;
                        dctx->value_attr = NULL;
                } else {
                        memcpy(&dctx->value_attr, &da, sizeof(da));
                }
 
                if (set_relative_attr) dctx->relative_attr = da;
                break;
 
        /* Deferred attribute, don't begin the TLV section automatically */
        case 1:
                break;
        }
 
        return 0;
}
 
static int dict_read_process_begin(dict_tokenize_ctx_t *dctx, char **argv, int argc, UNUSED fr_dict_attr_flags_t *base_flags)
{
        dict_tokenize_frame_t const     *frame;
        fr_dict_attr_t const            *da;
        fr_dict_attr_t const            *common;
 
        dctx->value_attr = NULL;
        dctx->relative_attr = NULL;
 
        if (argc != 1) {
                fr_strerror_const_push("Invalid BEGIN keyword.  Expected BEGIN <name>");
        error:
                return -1;
        }
 
        frame = dict_dctx_find_frame(dctx, NEST_ROOT | NEST_PROTOCOL | NEST_ATTRIBUTE);
        if (!fr_cond_assert_msg(frame, "Context stack doesn't have an attribute or dictionary "
                                "root to begin searching from %s[%d]", CURRENT_FILENAME(dctx), CURRENT_LINE(dctx)) ||
            !fr_cond_assert_msg(fr_type_is_structural(frame->da->type), "Context attribute is not structural %s[%d]",
                                CURRENT_FILENAME(dctx), CURRENT_LINE(dctx))) {
                return -1;
        }
 
        /*
         *      Not really a reference as we don't support any of the
         *      fancy syntaxes like refs do.  A straight OID string
         *      resolved from the current level of nesting is all we support.
         */
        da = fr_dict_attr_by_oid(NULL, frame->da, argv[0]);
        if (!da) {
                fr_strerror_printf_push("BEGIN '%s' not resolvable in context '%s'", argv[0], frame->da->name);
                goto error;
        }
 
        if (!fr_type_is_tlv(da->type) && !fr_type_is_struct(da->type)) {
                fr_strerror_printf_push("BEGIN %s should be a 'tlv' or 'struct', but is a '%s'",
                                        argv[0],
                                        fr_type_to_str(da->type));
                goto error;
        }
 
        common = fr_dict_attr_common_parent(frame->da, da, true);
        if (!common) {
                fr_strerror_printf_push("BEGIN %s should be a child of '%s'",
                                        argv[0], dctx->stack[dctx->stack_depth].da->name);
                goto error;
        }
 
        if (dict_dctx_push(dctx, da, NEST_ATTRIBUTE) < 0) goto error;
 
        return 0;
}
 
static int dict_read_process_begin_protocol(dict_tokenize_ctx_t *dctx, char **argv, int argc,
                                            UNUSED fr_dict_attr_flags_t *base_flags)
{
        fr_dict_t                       *found;
        dict_tokenize_frame_t const     *frame;
 
        dctx->value_attr = NULL;
        dctx->relative_attr = NULL;
 
        if (argc != 1) {
                fr_strerror_const_push("Invalid BEGIN-PROTOCOL entry");
        error:
                return -1;
        }
 
        /*
         *      If we're not parsing in the context of the internal
         *      dictionary, then we don't allow BEGIN-PROTOCOL
         *      statements.
         */
        if (dctx->dict != dict_gctx->internal) {
                fr_strerror_const_push("Nested BEGIN-PROTOCOL statements are not allowed");
                goto error;
        }
 
        found = dict_by_protocol_name(argv[0]);
        if (!found) {
                fr_strerror_printf("Unknown protocol '%s'", argv[0]);
                goto error;
        }
 
        frame = dict_dctx_find_frame(dctx, NEST_PROTOCOL);
        if (frame) {
                fr_strerror_printf_push("Nested BEGIN-PROTOCOL is forbidden.  Previous definition is at %s[%d]",
                                        frame->filename, frame->line);
                goto error;
        }
 
        /*
         *      Add a temporary fixup pool
         *
         *      @todo - make a nested ctx?
         */
        dict_fixup_init(NULL, &dctx->fixup);
 
        /*
         *      We're in the middle of loading this dictionary.  Tell
         *      fr_dict_protocol_afrom_file() to suppress recursive references.
         */
        found->loading = true;
 
        dctx->dict = found;
 
        if (dict_dctx_push(dctx, dctx->dict->root, NEST_PROTOCOL) < 0) goto error;
 
        return 0;
}
 
static int dict_read_process_begin_vendor(dict_tokenize_ctx_t *dctx, char **argv, int argc,
                                          UNUSED fr_dict_attr_flags_t *base_flags)
{
        fr_dict_vendor_t const          *vendor;
        fr_dict_attr_flags_t            flags;
 
        fr_dict_attr_t const            *vsa_da;
        fr_dict_attr_t const            *vendor_da;
        fr_dict_attr_t                  *new;
        dict_tokenize_frame_t const     *frame;
        char                            *p;
 
        dctx->value_attr = NULL;
        dctx->relative_attr = NULL;
 
        if (argc < 1) {
                fr_strerror_const_push("Invalid BEGIN-VENDOR entry");
        error:
                return -1;
        }
 
        vendor = fr_dict_vendor_by_name(dctx->dict, argv[0]);
        if (!vendor) {
                fr_strerror_printf_push("Unknown vendor '%s'", argv[0]);
                goto error;
        }
 
        /*
         *      Check for extended attr VSAs
         *
         *      BEGIN-VENDOR foo parent=Foo-Encapsulation-Attr
         */
        if (argc > 1) {
                fr_dict_attr_t const *da;
 
                if (strncmp(argv[1], "parent=", 7) != 0) {
                        fr_strerror_printf_push("BEGIN-VENDOR invalid argument (%s)", argv[1]);
                        goto error;
                }
 
                p = argv[1] + 7;
                da = fr_dict_attr_by_oid(NULL, dctx->stack[dctx->stack_depth].da, p);
                if (!da) {
                        fr_strerror_printf_push("BEGIN-VENDOR invalid argument (%s)", argv[1]);
                        goto error;
                }
 
                if (da->type != FR_TYPE_VSA) {
                        fr_strerror_printf_push("Invalid parent for BEGIN-VENDOR.  "
                                                "Attribute '%s' should be 'vsa' but is '%s'", p,
                                                fr_type_to_str(da->type));
                        goto error;
                }
 
                vsa_da = da;
 
        } else if (dctx->dict->vsa_parent) {
                /*
                 *      Check that the protocol-specific VSA parent exists.
                 */
                vsa_da = dict_attr_child_by_num(dctx->stack[dctx->stack_depth].da, dctx->dict->vsa_parent);
                if (!vsa_da) {
                        fr_strerror_printf_push("Failed finding VSA parent for Vendor %s",
                                                vendor->name);
                        goto error;
                }
 
        } else if (dctx->dict->string_based) {
                vsa_da = dctx->dict->root;
 
        } else {
                fr_strerror_printf_push("BEGIN-VENDOR is forbidden for protocol %s - it has no ATTRIBUTE of type 'vsa'",
                                        dctx->dict->root->name);
                goto error;
        }
 
        frame = dict_dctx_find_frame(dctx, NEST_VENDOR);
        if (frame) {
                fr_strerror_printf_push("Nested BEGIN-VENDOR is forbidden.  Previous definition is at %s[%d]",
                                        frame->filename, frame->line);
                goto error;
        }
 
        /*
         *      Create a VENDOR attribute on the fly, either in the context
         *      of the VSA (26) attribute.
         */
        vendor_da = dict_attr_child_by_num(vsa_da, vendor->pen);
        if (!vendor_da) {
                memset(&flags, 0, sizeof(flags));
 
                flags.type_size = dctx->dict->proto->default_type_size;
                flags.length = dctx->dict->proto->default_type_length;
 
                /*
                 *      See if this vendor has
                 *      specific sizes for type /
                 *      length.
                 *
                 *      @todo - Make this more protocol agnostic!
                 */
                if ((vsa_da->type == FR_TYPE_VSA) &&
                        (vsa_da->parent->flags.is_root)) {
                        fr_dict_vendor_t const *dv;
 
                        dv = fr_dict_vendor_by_num(dctx->dict, vendor->pen);
                        if (dv) {
                                flags.type_size = dv->type;
                                flags.length = dv->length;
                        }
                }
 
                new = dict_attr_alloc(dctx->dict->pool,
                                      vsa_da, argv[0], vendor->pen, FR_TYPE_VENDOR,
                                      &(dict_attr_args_t){ .flags = &flags });
                if (unlikely(!new)) goto error;
 
                if (dict_attr_child_add(UNCONST(fr_dict_attr_t *, vsa_da), new) < 0) {
                        talloc_free(new);
                        goto error;
                }
 
                if (dict_attr_add_to_namespace(UNCONST(fr_dict_attr_t *, vsa_da), new) < 0) {
                        talloc_free(new);
                        goto error;
                }
 
                vendor_da = new;
        } else {
                fr_assert(vendor_da->type == FR_TYPE_VENDOR);
        }
 
        if (dict_dctx_push(dctx, vendor_da, NEST_VENDOR) < 0) goto error;
 
        return 0;
}
 
/*
 *      Process the DEFINE command
 *
 *      Which is mostly like ATTRIBUTE, but does not have a number.
 */
static int dict_read_process_define(dict_tokenize_ctx_t *dctx, char **argv, int argc,
                                    fr_dict_attr_flags_t *base_flags)
{
        fr_dict_attr_t const            *parent;
        fr_dict_attr_t                  *da;
        dict_tokenize_frame_t const     *frame;
 
        if ((argc < 2) || (argc > 3)) {
                fr_strerror_const("Invalid DEFINE syntax");
                return -1;
        }
 
        if (dict_read_process_common(dctx, &da, argv[0], argv[1],
                                     (argc > 2) ? argv[2] : NULL, base_flags) < 0) {
                return -1;
        }
 
        /*
         *      Certain structural types MUST have numbers.
         */
        switch (da->type) {
        case FR_TYPE_VSA:
        case FR_TYPE_VENDOR:
                fr_strerror_printf("DEFINE cannot be used for type '%s'", argv[1]);
        error:
                talloc_free(da);
                return -1;
 
        default:
                break;
        }
 
        if (da->flags.extra && (da->flags.subtype == FLAG_BIT_FIELD)) {
                fr_strerror_const("Bit fields can only be defined as a MEMBER of a STRUCT");
                goto error;
        }
 
        frame = dict_dctx_unwind(dctx);
        if (!fr_cond_assert(frame && frame->da)) goto error;    /* Should have provided us with a parent */
 
        parent = frame->da;
 
        /*
         *      Members of a 'struct' MUST use MEMBER, not ATTRIBUTE.
         */
        if (parent->type == FR_TYPE_STRUCT) {
                fr_strerror_printf("Member %s of parent %s type 'struct' MUST use the \"MEMBER\" keyword",
                                   argv[0], parent->name);
                goto error;
        }
 
#ifdef STATIC_ANALYZER
        if (!dctx->dict) goto error;
#endif
 
        /*
         *      Since there is no number, the attribute cannot be
         *      encoded as a number.
         */
        da->flags.name_only = true;
 
        if (unlikely(dict_attr_parent_init(&da, parent) < 0)) goto error;
 
        /*
         *      Add an attribute number now so the allocations occur in order
         */
        if (unlikely(dict_attr_num_init_name_only(da) < 0)) goto error;
 
        /*
         *      Set the attribute name
         */
        if (unlikely(dict_attr_finalise(&da, argv[0]) < 0)) goto error;
 
        /*
         *      Check to see if this is a duplicate attribute
         *      and whether we should ignore it or error out...
         */
        switch (dict_attr_allow_dup(da)) {
        case 1:
                break;
 
        case 0:
                talloc_free(da);
                return 0;
 
        default:
                goto error;
        }
 
        /*
         *      Add the attribute we allocated earlier
         */
        switch (dict_attr_add_or_fixup(&dctx->fixup, &da)) {
        default:
                goto error;
 
        /* New attribute, fixup stack */
        case 0:
                if (dict_set_value_attr(dctx, da) < 0) return -1;
 
                if (da->type == FR_TYPE_TLV) {
                        dctx->relative_attr = da;
                } else {
                        dctx->relative_attr = NULL;
                }
                break;
 
        /* Deferred attribute, don't begin the TLV section automatically */
        case 1:
                break;
        }
 
        return 0;
}
 
static int dict_read_process_end(dict_tokenize_ctx_t *dctx, char **argv, int argc,
                                 UNUSED fr_dict_attr_flags_t *base_flags)
{
        fr_dict_attr_t const *current;
        fr_dict_attr_t const *da;
        dict_tokenize_frame_t const *frame;
 
        dctx->value_attr = NULL;
        dctx->relative_attr = NULL;
 
        if (argc > 2) {
                fr_strerror_const("Invalid END syntax, expected END <ref>");
                goto error;
        }
 
        /*
         *      Unwind until we hit an attribute nesting section
         */
        if (!dict_dctx_unwind_until(dctx, NEST_ATTRIBUTE)) {
                fr_strerror_const("Unbalanced BEGIN and END keywords");
        error:
                return -1;
        }
 
        /*
         *      Pop the stack to get the attribute we're ending.
         */
        current = dict_dctx_pop(dctx)->da;
 
        /*
         *      No checks on the attribute, we're just popping _A_ frame,
         *      we don't care what attribute it represents.
         */
        if (argc == 1) return 0;
 
        /*
         *      This is where we'll have begun the previous search to
         *      evaluate the BEGIN keyword.
         */
        frame = dict_dctx_find_frame(dctx, NEST_ROOT | NEST_PROTOCOL | NEST_ATTRIBUTE);
        if (!fr_cond_assert(frame)) goto error;
 
        da = fr_dict_attr_by_oid(NULL, frame->da, argv[0]);
        if (!da) {
                fr_strerror_const_push("Failed resolving attribute in BEGIN entry");
                goto error;
        }
 
        if (da != current) {
                fr_strerror_printf_push("END %s does not match previous BEGIN %s", argv[0], current->name);
                goto error;
        }
 
        return 0;
}
 
static int dict_read_process_end_protocol(dict_tokenize_ctx_t *dctx, char **argv, int argc,
                                          UNUSED fr_dict_attr_flags_t *base_flags)
{
        fr_dict_t const *found;
 
        dctx->value_attr = NULL;
        dctx->relative_attr = NULL;
 
        if (argc != 1) {
                fr_strerror_const("Invalid END-PROTOCOL entry");
        error:
                return -1;
        }
 
        found = dict_by_protocol_name(argv[0]);
        if (!found) {
                fr_strerror_printf("END-PROTOCOL %s does not refer to a valid protocol", argv[0]);
                goto error;
        }
 
        if (found != dctx->dict) {
                fr_strerror_printf("END-PROTOCOL %s does not match previous BEGIN-PROTOCOL %s",
                                   argv[0], dctx->dict->root->name);
                goto error;
        }
 
        /*
         *      Pop the stack until we get to a PROTOCOL nesting.
         */
        while ((dctx->stack_depth > 0) && (dctx->stack[dctx->stack_depth].nest != NEST_PROTOCOL)) {
                if (dctx->stack[dctx->stack_depth].nest != NEST_NONE) {
                        fr_strerror_printf_push("END-PROTOCOL %s with mismatched BEGIN-??? %s", argv[0],
                                dctx->stack[dctx->stack_depth].da->name);
                        goto error;
                }
 
                dctx->stack_depth--;
        }
 
        if (dctx->stack_depth == 0) {
                fr_strerror_printf_push("END-PROTOCOL %s with no previous BEGIN-PROTOCOL", argv[0]);
                goto error;
        }
 
        if (found->root != dctx->stack[dctx->stack_depth].da) {
                fr_strerror_printf_push("END-PROTOCOL %s does not match previous BEGIN-PROTOCOL %s", argv[0],
                                        dctx->stack[dctx->stack_depth].da->name);
                goto error;
        }
 
        /*
         *      Applies fixups to any attributes added
         *      to the protocol dictionary.  Note that
         *      the finalise function prints out the
         *      original filename / line of the
         *      error. So we don't need to do that
         *      here.
         */
        if (dict_finalise(dctx) < 0) goto error;
 
        dctx->stack_depth--;
        dctx->dict = dctx->stack[dctx->stack_depth].dict;
 
        return 0;
}
 
static int dict_read_process_end_vendor(dict_tokenize_ctx_t *dctx, char **argv, int argc,
                                        UNUSED fr_dict_attr_flags_t *base_flags)
{
        fr_dict_vendor_t const *vendor;
 
        dctx->value_attr = NULL;
        dctx->relative_attr = NULL;
 
        if (argc != 1) {
                fr_strerror_const_push("Invalid END-VENDOR entry");
        error:
                return -1;
        }
 
        vendor = fr_dict_vendor_by_name(dctx->dict, argv[0]);
        if (!vendor) {
                fr_strerror_printf_push("Unknown vendor '%s'", argv[0]);
                goto error;
        }
 
        /*
         *      Pop the stack until we get to a VENDOR nesting.
         */
        while ((dctx->stack_depth > 0) && (dctx->stack[dctx->stack_depth].nest != NEST_VENDOR)) {
                if (dctx->stack[dctx->stack_depth].nest != NEST_NONE) {
                        fr_strerror_printf_push("END-VENDOR %s with mismatched BEGIN-??? %s", argv[0],
                                dctx->stack[dctx->stack_depth].da->name);
                        goto error;
                }
 
                dctx->stack_depth--;
        }
 
        if (dctx->stack_depth == 0) {
                fr_strerror_printf_push("END-VENDOR %s with no previous BEGIN-VENDOR", argv[0]);
                goto error;
        }
 
        if (vendor->pen != dctx->stack[dctx->stack_depth].da->attr) {
                fr_strerror_printf_push("END-VENDOR %s does not match previous BEGIN-VENDOR %s", argv[0],
                                        dctx->stack[dctx->stack_depth].da->name);
                goto error;
        }
 
        dctx->stack_depth--;
 
        return 0;
}
 
/*
 *      Process the ENUM command
 */
static int dict_read_process_enum(dict_tokenize_ctx_t *dctx, char **argv, int argc,
                                  fr_dict_attr_flags_t *base_flags)
{
        fr_dict_attr_t const    *parent;
        fr_dict_attr_t          *da = NULL;
 
        if (argc != 2) {
                fr_strerror_const("Invalid ENUM syntax");
                return -1;
        }
 
        /*
         *      Dictionaries need to have real names, not shitty ones.
         */
        if (strncmp(argv[0], "Attr-", 5) == 0) {
                fr_strerror_const("Invalid ENUM name");
                return -1;
        }
 
#ifdef STATIC_ANALYZER
        if (!dctx->dict) goto error;
#endif
 
        /*
         *      Allocate the attribute here, and then fill in the fields
         *      as we start parsing the various elements of the definition.
         */
        da = dict_attr_alloc_null(dctx->dict->pool, dctx->dict->proto);
        if (unlikely(da == NULL)) return -1;
        dict_attr_location_set(dctx, da);
        da->dict = dctx->dict;
 
        /*
         *      Set the attribute flags from the base flags.
         */
        memcpy(&da->flags, base_flags, sizeof(da->flags));
 
        da->flags.name_only = true;             /* values for ENUM are irrelevant */
        da->flags.internal = true;              /* ENUMs will never get encoded into a protocol */
#if 0
        flags.is_enum = true;           /* it's an enum, and can't be assigned to a #fr_pair_t */
#endif
 
        /*
         *      Set the base type of the attribute.
         */
        if (dict_process_type_field(dctx, argv[1], &da) < 0) {
        error:
                talloc_free(da);
                return -1;
        }
 
        if (da->flags.extra && (da->flags.subtype == FLAG_BIT_FIELD)) {
                fr_strerror_const("Bit fields can only be defined as a MEMBER of a STRUCT");
                goto error;
        }
 
        switch (da->type) {
        case FR_TYPE_LEAF:
                break;
 
        default:
                fr_strerror_printf("ENUMs can only be a leaf type, not %s",
                                   fr_type_to_str(da->type));
                break;
        }
 
        parent = dctx->stack[dctx->stack_depth].da;
        if (!parent) {
                fr_strerror_const("Invalid location for ENUM");
                goto error;
        }
 
        /*
         *      ENUMs cannot have a flag field, so we don't parse that.
         *
         *      Maybe we do want a flag field for named time deltas?
         */
 
        if (unlikely(dict_attr_parent_init(&da, parent) < 0)) goto error;
        if (unlikely(dict_attr_finalise(&da, argv[0]) < 0)) goto error;
 
        /*
         *      Add the attribute we allocated earlier
         */
        switch (dict_attr_add_or_fixup(&dctx->fixup, &da)) {
        default:
                goto error;
 
        case 0:
                memcpy(&dctx->value_attr, &da, sizeof(da));
                break;
 
        case 1:
                break;
        }
 
        return 0;
}
 
/*
 *      Process the FLAGS command
 */
static int dict_read_process_flags(UNUSED dict_tokenize_ctx_t *dctx, char **argv, int argc,
                                   fr_dict_attr_flags_t *base_flags)
{
        bool sense = true;
 
        if (argc == 1) {
                char *p;
 
                p = argv[0];
                if (*p == '!') {
                        sense = false;
                        p++;
                }
 
                if (strcmp(p, "internal") == 0) {
                        base_flags->internal = sense;
                        return 0;
                }
        }
 
        fr_strerror_const("Invalid FLAGS syntax");
        return -1;
}
 
/*
 *      Process the MEMBER command
 */
static int dict_read_process_member(dict_tokenize_ctx_t *dctx, char **argv, int argc,
                                    fr_dict_attr_flags_t *base_flags)
{
        fr_dict_attr_t          *da;
 
        if ((argc < 2) || (argc > 3)) {
                fr_strerror_const("Invalid MEMBER syntax");
                return -1;
        }
 
        if (dctx->stack[dctx->stack_depth].da->type != FR_TYPE_STRUCT) {
                fr_strerror_printf("MEMBER can only be used for ATTRIBUTEs of type 'struct', not %s of type %s",
                                   dctx->stack[dctx->stack_depth].da->name,
                                   fr_type_to_str(dctx->stack[dctx->stack_depth].da->type));
                return -1;
        }
 
        if (dict_read_process_common(dctx, &da, argv[0], argv[1],
                                     (argc > 2) ? argv[2] : NULL, base_flags) < 0) {
                return -1;
        }
 
#ifdef STATIC_ANALYZER
        if (!dctx->dict) goto error;
#endif
 
        /*
         *      If our parent is a fixed-size struct, then we have to be fixed-size, too.
         */
        da->flags.is_known_width |= dctx->stack[dctx->stack_depth].da->flags.is_known_width;
 
        /*
         *      Double check bit field magic
         */
        if (dctx->stack[dctx->stack_depth].member_num > 0) {
                fr_dict_attr_t const *previous;
 
                previous = dict_attr_child_by_num(dctx->stack[dctx->stack_depth].da,
                                                  dctx->stack[dctx->stack_depth].member_num);
                /*
                 *      Check that the previous bit field ended on a
                 *      byte boundary.
                 *
                 *      Note that the previous attribute might be a deferred TLV, in which case it doesn't
                 *      exist.  That's fine.
                 */
                if (previous && previous->flags.extra && (previous->flags.subtype == FLAG_BIT_FIELD)) {
                        /*
                         *      This attribute is a bit field.  Keep
                         *      track of where in the byte we are
                         *      located.
                         */
                        if (da->flags.extra && (da->flags.subtype == FLAG_BIT_FIELD)) {
                                da->flags.flag_byte_offset = (da->flags.length + previous->flags.flag_byte_offset) & 0x07;
 
                        } else {
                                if (previous->flags.flag_byte_offset != 0) {
                                        fr_strerror_printf("Previous bitfield %s did not end on a byte boundary",
                                                           previous->name);
                                error:
                                        talloc_free(da);
                                        return -1;
                                }
                        }
                }
        }
 
        /*
         *      Check if the parent 'struct' is fixed size.  And if
         *      so, complain if we're adding a variable sized member.
         */
        if (dctx->stack[dctx->stack_depth].struct_is_closed) {
                fr_strerror_printf("Cannot add MEMBER to 'struct' %s after a variable sized member %s",
                                   dctx->stack[dctx->stack_depth].da->name,
                                   dctx->stack[dctx->stack_depth].struct_is_closed->name);
                goto error;
        }
 
        /*
         *      Ensure that no previous child has "key" or "length" set.
         */
        if (da->type == FR_TYPE_TLV) {
                fr_dict_attr_t const *key;
                int i;
 
                /*
                 *      @todo - cache the key field in the stack frame, so we don't have to loop over the children.
                 */
                for (i = 1; i <= dctx->stack[dctx->stack_depth].member_num; i++) {
                        key = dict_attr_child_by_num(dctx->stack[dctx->stack_depth].da, i);
                        if (!key) continue; /* really should be WTF? */
 
                        if (fr_dict_attr_is_key_field(key)) {
                                fr_strerror_printf("'struct' %s has a 'key' field %s, and cannot end with a TLV %s",
                                                   dctx->stack[dctx->stack_depth].da->name, key->name, argv[0]);
                                goto error;
                        }
 
                        if (da_is_length_field(key)) {
                                fr_strerror_printf("'struct' %s has a 'length' field %s, and cannot end with a TLV %s",
                                                   dctx->stack[dctx->stack_depth].da->name, key->name, argv[0]);
                                goto error;
                        }
                }
        }
 
        if (unlikely(dict_attr_parent_init(&da, dctx->stack[dctx->stack_depth].da) < 0)) goto error;
        if (unlikely(dict_attr_num_init(da, ++dctx->stack[dctx->stack_depth].member_num) < 0)) goto error;
        if (unlikely(dict_attr_finalise(&da, argv[0]) < 0)) goto error;
 
        /*
         *      Check to see if this is a duplicate attribute
         *      and whether we should ignore it or error out...
         */
        switch (dict_attr_allow_dup(da)) {
        case 1:
                break;
 
        case 0:
                talloc_free(da);
                return 0;
 
        default:
                goto error;
        }
 
        switch (dict_attr_add_or_fixup(&dctx->fixup, &da)) {
        default:
                goto error;
 
        /* New attribute, fixup stack */
        case 0:
                /*
                *       A 'struct' can have a MEMBER of type 'tlv', but ONLY
                *       as the last entry in the 'struct'.  If we see that,
                *       set the previous attribute to the TLV we just added.
                *       This allows the children of the TLV to be parsed as
                *       partial OIDs, so we don't need to know the full path
                *       to them.
                */
                if (da->type == FR_TYPE_TLV) {
                        dctx->relative_attr = dict_attr_child_by_num(dctx->stack[dctx->stack_depth].da,
                                                                    dctx->stack[dctx->stack_depth].member_num);
                        if (dctx->relative_attr && (dict_dctx_push(dctx, dctx->relative_attr, 0) < 0)) return -1;
                        return 0;
 
                }
 
                /*
                 *      Add the size of this member to the parent struct.
                 */
                if (dctx->stack[dctx->stack_depth].da->flags.length) {
                        /*
                         *      Fixed-size struct can't have MEMBERs of unknown sizes.
                         */
                        if (!da->flags.is_known_width) {
                                fr_strerror_printf("'struct' %s has fixed size %u, but member %s is of unknown size",
                                                   dctx->stack[dctx->stack_depth].da->name, dctx->stack[dctx->stack_depth].da->flags.length,
                                                   argv[0]);
                                return -1;
                        }
 
                        dctx->stack[dctx->stack_depth].struct_size += da->flags.length;
 
                }
 
                /*
                 *      Check for overflow.
                 */
                if (dctx->stack[dctx->stack_depth].da->flags.length &&
                    (dctx->stack[dctx->stack_depth].struct_size > dctx->stack[dctx->stack_depth].da->flags.length)) {
                        fr_strerror_printf("'struct' %s has fixed size %u, but member %s overflows that length",
                                           dctx->stack[dctx->stack_depth].da->name, dctx->stack[dctx->stack_depth].da->flags.length,
                                           argv[0]);
                        return -1;
                }
 
                if (dict_set_value_attr(dctx, da) < 0) return -1;
 
                /*
                 *      Check if this MEMBER closes the structure.
                 *
                 *      @todo - close this struct if the child struct is variable sized.  For now, it
                 *      looks like most child structs are at the end of the parent.
                 *
                 *      The solution is to update the unwind() function to check if the da we've
                 *      unwound to is a struct, and then if so... get the last child, and mark it
                 *      closed.
                 */
                if (!da->flags.is_known_width) dctx->stack[dctx->stack_depth].struct_is_closed = da;
                break;
 
        /* Deferred attribute, don't begin the TLV section automatically */
        case 1:
                break;
        }
 
        return 0;
}
 
/** Process a STRUCT name attr value
 *
 * Define struct 'name' when key 'attr' has 'value'.
 *
 *  Which MUST be a sub-structure of another struct
 */
static int dict_read_process_struct(dict_tokenize_ctx_t *dctx, char **argv, int argc,
                                    UNUSED fr_dict_attr_flags_t *base_flags)
{
        fr_value_box_t                  value = FR_VALUE_BOX_INITIALISER_NULL(value);
        int                             i;
        fr_dict_attr_t const            *parent = NULL;
        unsigned int                    attr;
        char                            *key_attr = argv[1];
        char                            *name = argv[0];
        fr_dict_attr_t                  *da;
 
        if ((argc < 3) || (argc > 4)) {
                fr_strerror_const("Invalid STRUCT syntax");
                return -1;
        }
 
        fr_assert(dctx->stack_depth > 0);
 
        /*
         *      Unwind the stack until we find a parent which has a child named "key_attr"
         */
        for (i = dctx->stack_depth; i > 0; i--) {
                parent = dict_attr_by_name(NULL, dctx->stack[i].da, key_attr);
                if (parent) {
                        dctx->stack_depth = i;
                        break;
                }
        }
 
        /*
         *      Else maybe it's a fully qualified name?
         */
        if (!parent) {
                parent = fr_dict_attr_by_oid(NULL, dctx->stack[dctx->stack_depth].da->dict->root, key_attr);
        }
 
        if (!parent) {
                fr_strerror_printf("Invalid STRUCT definition, unknown key attribute %s",
                                   key_attr);
                return -1;
        }
 
        if (!fr_dict_attr_is_key_field(parent)) {
                fr_strerror_printf("Attribute '%s' is not a 'key' attribute", key_attr);
                return -1;
        }
 
        /*
         *      Rely on dict_attr_flags_valid() to ensure that
         *      da->type is an unsigned integer, AND that da->parent->type == struct
         */
        if (!fr_cond_assert(parent->parent->type == FR_TYPE_STRUCT)) return -1;
 
        /*
         *      Parse the value.
         */
        if (fr_value_box_from_str(NULL, &value, parent->type, NULL, argv[2], strlen(argv[2]), NULL, false) < 0) {
                fr_strerror_printf_push("Invalid value for STRUCT \"%s\"", argv[2]);
                return -1;
        }
 
        /*
         *      Allocate the attribute here, and then fill in the fields
         *      as we start parsing the various elements of the definition.
         */
        da = dict_attr_alloc_null(dctx->dict->pool, dctx->dict->proto);
        if (unlikely(da == NULL)) return -1;
        dict_attr_location_set(dctx, da);
        da->dict = dctx->dict;
 
        if (unlikely(dict_attr_type_init(&da, FR_TYPE_STRUCT) < 0)) {
        error:
                talloc_free(da);
                return -1;
        }
 
        /*
         *      Structs can be prefixed with 16-bit lengths, but not
         *      with any other type of length.
         */
        if (argc == 4) {
                if (dict_process_flag_field(dctx, argv[3], &da) < 0) goto error;
        }
 
        /*
         *      @todo - auto-number from a parent UNION, instead of overloading the value.
         */
        switch (parent->type) {
        case FR_TYPE_UINT8:
                attr = value.vb_uint8;
                break;
 
        case FR_TYPE_UINT16:
                attr = value.vb_uint16;
                break;
 
        case FR_TYPE_UINT32:
                attr = value.vb_uint32;
                break;
 
        default:
                fr_strerror_printf("Invalid data type in attribute '%s'", key_attr);
                return -1;
        }
 
        if (unlikely(dict_attr_num_init(da, attr) < 0)) goto error;
        if (unlikely(dict_attr_parent_init(&da, parent) < 0)) goto error;
        if (unlikely(dict_attr_finalise(&da, name) < 0)) goto error;
 
        /*
         *      Check to see if this is a duplicate attribute
         *      and whether we should ignore it or error out...
         */
        switch (dict_attr_allow_dup(da)) {
        case 1:
                break;
 
        case 0:
                talloc_free(da);
                return 0;
 
        default:
                goto error;
        }
 
        /*
         *      Add the keyed STRUCT to the global namespace, and as a child of "parent".
         */
        switch (dict_attr_add_or_fixup(&dctx->fixup, &da)) {
        default:
                goto error;
 
        /* FIXME: Should dict_attr_enum_add_name also be called in the fixup code? */
        case 0:
                da = dict_attr_by_name(NULL, parent, name);
                if (!da) return -1;
 
                /*
                 *      A STRUCT definition is an implicit BEGIN-STRUCT.
                 */
                dctx->relative_attr = NULL;
                if (dict_dctx_push(dctx, da, 0) < 0) return -1;
 
                /*
                *       Add the VALUE to the parent attribute, and ensure that
                *       the VALUE also contains a pointer to the child struct.
                */
                if (dict_attr_enum_add_name(fr_dict_attr_unconst(parent), name, &value, false, true, da) < 0) {
                        fr_value_box_clear(&value);
                        return -1;
                }
                fr_value_box_clear(&value);
                break;
 
        case 1:
                break;
        }
 
        return 0;
}
 
/** Process a value alias
 *
 */
static int dict_read_process_value(dict_tokenize_ctx_t *dctx, char **argv, int argc,
                                   UNUSED fr_dict_attr_flags_t *base_flags)
{
        fr_dict_attr_t          *da;
        fr_value_box_t          value = FR_VALUE_BOX_INITIALISER_NULL(value);
        fr_slen_t               enum_len;
        fr_dict_attr_t const    *parent = dctx->stack[dctx->stack_depth].da;
 
        if (argc != 3) {
                fr_strerror_const("Invalid VALUE syntax");
                return -1;
        }
 
        /*
         *      Most VALUEs are bunched together by ATTRIBUTE.  We can
         *      save a lot of lookups on dictionary initialization by
         *      caching the last attribute for a VALUE.
         *
         *      If it's not the same, we look up the attribute in the
         *      current context, which is generally:
         *
         *      * the current attribute of type `struct`
         *      * if no `struct`, then the VENDOR for VSAs
         *      * if no VENDOR, then the dictionary root
         */
        if (!dctx->value_attr || (strcasecmp(argv[0], dctx->value_attr->name) != 0)) {
                fr_dict_attr_t const *tmp;
 
                if (!(tmp = fr_dict_attr_by_oid(NULL, parent, argv[0]))) goto fixup;
                dctx->value_attr = fr_dict_attr_unconst(tmp);
        }
        da = dctx->value_attr;
 
        /*
         *      Verify the enum name matches the expected from.
         */
        enum_len = (fr_slen_t)strlen(argv[1]);
        if (fr_dict_enum_name_from_substr(NULL, NULL, &FR_SBUFF_IN(argv[1], enum_len), NULL) != enum_len) {
                fr_strerror_printf_push("Invalid VALUE name '%s' for attribute '%s'", argv[1], da->name);
                return -1;
        }
 
        /*
         *      Remember which attribute is associated with this
         *      value.  This allows us to define enum
         *      values before the attribute exists, and fix them
         *      up later.
         */
        if (!da) {
        fixup:
                if (!fr_cond_assert_msg(dctx->fixup.pool, "fixup pool context invalid")) return -1;
 
                if (dict_fixup_enumv_enqueue(&dctx->fixup,
                                     CURRENT_FRAME(dctx)->filename, CURRENT_FRAME(dctx)->line,
                                     argv[0], strlen(argv[0]),
                                     argv[1], strlen(argv[1]),
                                     argv[2], strlen(argv[2]), parent) < 0) {
                        fr_strerror_const("Out of memory");
                        return -1;
                }
                return 0;
        }
 
        /*
         *      Only a leaf types can have values defined.
         */
        if (!fr_type_is_leaf(da->type)) {
                fr_strerror_printf_push("Cannot define VALUE for attribute '%s' of data type '%s'", da->name,
                                        fr_type_to_str(da->type));
                return -1;
        }
 
        if (fr_value_box_from_str(NULL, &value, da->type, NULL,
                                  argv[2], strlen(argv[2]),
                                  NULL, false) < 0) {
                fr_strerror_printf_push("Invalid VALUE '%s' for attribute '%s' of data type '%s'",
                                        argv[2],
                                        da->name,
                                        fr_type_to_str(da->type));
                return -1;
        }
 
        if (fr_dict_enum_add_name(da, argv[1], &value, false, true) < 0) {
                fr_value_box_clear(&value);
                return -1;
        }
        fr_value_box_clear(&value);
 
        return 0;
}
 
/*
 *      Process the VENDOR command
 */
static int dict_read_process_vendor(dict_tokenize_ctx_t *dctx, char **argv, int argc, UNUSED fr_dict_attr_flags_t *base_flags)
{
        unsigned int                    value;
        int                             type, length;
        bool                            continuation = false;
        fr_dict_vendor_t const          *dv;
        fr_dict_vendor_t                *mutable;
        fr_dict_t                       *dict = dctx->dict;
 
        dctx->value_attr = NULL;
        dctx->relative_attr = NULL;
 
        if ((argc < 2) || (argc > 3)) {
                fr_strerror_const("Invalid VENDOR syntax");
                return -1;
        }
 
        /*
         *       Validate all entries
         */
        if (!dict_read_sscanf_i(&value, argv[1])) {
                fr_strerror_const("Invalid number in VENDOR");
                return -1;
        }
 
        /*
         *      Look for a format statement.  Allow it to over-ride the hard-coded formats below.
         */
        if (argc == 3) {
                if (dict_read_parse_format(argv[2], &type, &length, &continuation) < 0) return -1;
 
        } else {
                type = length = 1;
        }
 
        /* Create a new VENDOR entry for the list */
        if (dict_vendor_add(dict, argv[0], value) < 0) return -1;
 
        dv = fr_dict_vendor_by_num(dict, value);
        if (!dv) {
                fr_strerror_const("Failed adding format for VENDOR");
                return -1;
        }
 
        mutable = UNCONST(fr_dict_vendor_t *, dv);
        mutable->type = type;
        mutable->length = length;
        mutable->continuation = continuation;
 
        return 0;
}
 
/** Register the specified dictionary as a protocol dictionary
 *
 * Allows vendor and TLV context to persist across $INCLUDEs
 */
static int dict_read_process_protocol(dict_tokenize_ctx_t *dctx, char **argv, int argc, UNUSED fr_dict_attr_flags_t *base_flag)
{
        unsigned int    value;
        unsigned int    type_size = 0;
        fr_dict_t       *dict;
        fr_dict_attr_t  *mutable;
        bool            require_dl = false;
        bool            string_based = false;
 
        dctx->value_attr = NULL;
        dctx->relative_attr = NULL;
 
        if ((argc < 2) || (argc > 3)) {
                fr_strerror_const("Missing arguments after PROTOCOL.  Expected PROTOCOL <num> <name>");
                return -1;
        }
 
        /*
         *       Validate all entries
         */
        if (!dict_read_sscanf_i(&value, argv[1])) {
                fr_strerror_printf("Invalid number '%s' following PROTOCOL", argv[1]);
                return -1;
        }
 
        /*
         *      255 protocols FR_TYPE_GROUP type_size hack
         */
        if (!value) {
                fr_strerror_printf("Invalid value '%u' following PROTOCOL", value);
                return -1;
        }
 
        /*
         *      Look for a format statement.  This may specify the
         *      type length of the protocol's types.
         */
        if (argc == 3) {
                char const *p;
                char *q;
 
                /*
                 *      For now, we don't allow multiple options here.
                 *
                 *      @todo - allow multiple options.
                 */
                if (strcmp(argv[2], "verify=lib") == 0) {
                        require_dl = true;
                        goto post_option;
                }
 
                if (strcmp(argv[2], "format=string") == 0) {
                        type_size = 4;
                        string_based = true;
                        goto post_option;
                }
 
                if (strncasecmp(argv[2], "format=", 7) != 0) {
                        fr_strerror_printf("Invalid format for PROTOCOL.  Expected 'format=', got '%s'", argv[2]);
                        return -1;
                }
                p = argv[2] + 7;
 
                type_size = strtoul(p, &q, 10);
                if (q != (p + strlen(p))) {
                        fr_strerror_printf("Found trailing garbage '%s' after format specifier", p);
                        return -1;
                }
        }
post_option:
 
        /*
         *      Cross check name / number.
         */
        dict = dict_by_protocol_name(argv[0]);
        if (dict) {
#ifdef STATIC_ANALYZER
                if (!dict->root) return -1;
#endif
 
                if (dict->root->attr != value) {
                        fr_strerror_printf("Conflicting numbers %u vs %u for PROTOCOL \"%s\"",
                                           dict->root->attr, value, dict->root->name);
                        return -1;
                }
 
        } else if ((dict = dict_by_protocol_num(value)) != NULL) {
#ifdef STATIC_ANALYZER
                if (!dict->root || !dict->root->name || !argv[0]) return -1;
#endif
 
                if (strcasecmp(dict->root->name, argv[0]) != 0) {
                        fr_strerror_printf("Conflicting names current \"%s\" vs new \"%s\" for PROTOCOL %u",
                                           dict->root->name, argv[0], dict->root->attr);
                        return -1;
                }
        }
 
        /*
         *      And check types no matter what.
         */
        if (dict) {
                if (type_size && (dict->root->flags.type_size != type_size)) {
                        fr_strerror_printf("Conflicting flags for PROTOCOL \"%s\" (current %d versus new %u)",
                                           dict->root->name, dict->root->flags.type_size, type_size);
                        return -1;
                }
                goto done;
        }
 
        dict = dict_alloc(dict_gctx);
 
        /*
         *      Try to load protocol-specific validation routines.
         *      Some protocols don't need them, so it's OK if the
         *      validation routines don't exist.
         */
        if ((dict_dlopen(dict, argv[0]) < 0) && require_dl) {
        error:
                talloc_free(dict);
                return -1;
        }
 
        /*
         *      Set the root attribute with the protocol name
         */
        if (dict_root_set(dict, argv[0], value) < 0) goto error;
 
        if (dict_protocol_add(dict) < 0) goto error;
 
        mutable = UNCONST(fr_dict_attr_t *, dict->root);
        dict->string_based = string_based;
        if (!type_size) {
                mutable->flags.type_size = dict->proto->default_type_size;
                mutable->flags.length = dict->proto->default_type_length;
        } else {
                mutable->flags.type_size = type_size;
                mutable->flags.length = 1; /* who knows... */
        }
 
done:
        /*
         *      Make the root available on the stack, in case
         *      something wants to begin it...
         */
        if (unlikely(dict_dctx_push_or_update(dctx, dict->root, NEST_NONE) < 0)) goto error;
 
        return 0;
}
 
/** Maintain a linked list of filenames which we've seen loading this dictionary
 *
 * This is used for debug messages, so we have a copy of the original file path
 * that we can reference from fr_dict_attr_t without having the memory bloat of
 * assigning a buffer to every attribute.
 */
static inline int dict_filename_add(char **filename_out, fr_dict_t *dict, char const *filename)
{
        fr_dict_filename_t *file;
 
        file = talloc_zero(dict, fr_dict_filename_t);
        if (unlikely(file == NULL)) {
        oom:
                fr_strerror_const("Out of memory");
                return -1;
        }
        *filename_out = file->filename = talloc_typed_strdup(dict, filename);
        if (unlikely(*filename_out == NULL)) goto oom;
 
        fr_dlist_insert_tail(&dict->filenames, file);
 
        return 0;
}
 
#ifndef NDEBUG
/** See if we have already loaded the file,
 *
 */
static inline bool dict_filename_loaded(fr_dict_t *dict, char const *filename)
{
        fr_dict_filename_t *file;
 
        for (file = (fr_dict_filename_t *) fr_dlist_head(&dict->filenames);
             file != NULL;
             file = (fr_dict_filename_t *) fr_dlist_next(&dict->filenames, &file->entry)) {
                if (strcmp(file->filename, filename) == 0) return true;
        }
 
        return false;
}
#endif
 
static int dict_struct_finalise(dict_tokenize_ctx_t *dctx)
{
        fr_dict_attr_t const *da;
 
        da = dctx->stack[dctx->stack_depth].da;
        if (da->type == FR_TYPE_STRUCT) {
                /*
                 *      The structure was fixed-size,
                 *      but the fields don't fill it.
                 *      That's an error.
                 *
                 *      Since process_member() checks
                 *      for overflow, the check here
                 *      is really only for underflow.
                 */
                if (da->flags.length && (dctx->stack[dctx->stack_depth].struct_size != da->flags.length)) {
                        fr_strerror_printf("MEMBERs of %s struct[%u] do not exactly fill the fixed-size structure",
                                        da->name, da->flags.length);
                        return -1;
                }
 
                /*
                 *      If the structure is fixed
                 *      size, AND small enough to fit
                 *      into an 8-bit length field,
                 *      then update the length field
                 *      with the structure size/
                 */
                if (dctx->stack[dctx->stack_depth].struct_size <= 255) {
                        UNCONST(fr_dict_attr_t *, da)->flags.length = dctx->stack[dctx->stack_depth].struct_size;
                } /* else length 0 means "unknown / variable size / too large */
        } else {
                fr_assert_msg(da->type == FR_TYPE_TLV, "Expected parent type of 'tlv', got '%s'", fr_type_to_str(da->type));
        }
 
        return 0;
}
 
/** Process an inline BEGIN PROTOCOL block
 */
static int dict_begin_protocol(dict_tokenize_ctx_t *dctx)
{
        fr_dict_attr_t const *da;
 
        ASSERT_CURRENT_NEST(dctx, NEST_NONE);
        da = CURRENT_DA(dctx);
        fr_assert_msg(fr_type_is_tlv(da->type), "Expected dictionary root to be a tlv, got '%s'", fr_type_to_str(da->type));
        fr_assert(da->flags.is_root);
 
        dctx->dict = da->dict;
 
        /*
         *      Push a PROTOCOL block onto the stack
         */
        return dict_dctx_push(dctx, da, NEST_PROTOCOL);
}
 
/** Keyword parser
 *
 * @param[in] dctx              containing the dictionary we're currently parsing.
 * @param[in] argv              arguments to the keyword.
 * @param[in] argc              number of arguments.
 * @param[in] base_flags        set in the context of the current file.
 * @return
 *      - 0 on success.
 *      - -1 on failure.
 */
typedef int (*fr_dict_keyword_parse_t)(dict_tokenize_ctx_t *dctx, char **argv, int argc, fr_dict_attr_flags_t *base_flags);
 
/** Pushes a new frame onto the top of the stack based on the current frame
 *
 * Whenever a protocol, vendor, or attribute is defined in the dictionary it either mutates or
 * pushes a new NONE frame onto the stack.  This holds the last defined object at a given level
 * of nesting.
 *
 * This function is used to push an additional frame onto the stack, effectively entering the
 * context of the last defined object at a given level of nesting
 *
 * @param[in] dctx      Contains the current state of the dictionary parser.
 *                      Used to track what PROTOCOL, VENDOR or TLV block
 *                      we're in.
 * @return
 *      - 0 on success.
 *      - -1 on failure.
 */
typedef int (*fr_dict_section_begin_t)(dict_tokenize_ctx_t *dctx);
 
typedef struct {
        fr_dict_keyword_parse_t         parse;                          //!< Function to parse the keyword with.
        fr_dict_section_begin_t         begin;                          //!< Can have a BEGIN prefix
} fr_dict_keyword_parser_t;
 
typedef struct {
        fr_table_elem_name_t            name;                           //!< Name of the keyword, e.g. "ATTRIBUTE"
        fr_dict_keyword_parser_t        value;                          //!< Value to return from lookup.
} fr_dict_keyword_t;
 
static TABLE_TYPE_NAME_FUNC_RPTR(table_sorted_value_by_str, fr_dict_keyword_t const *,
                                 fr_dict_keyword, fr_dict_keyword_parser_t const *, fr_dict_keyword_parser_t const *)
 
/** Parse a dictionary file
 *
 * @param[in] dctx      Contains the current state of the dictionary parser.
 *                      Used to track what PROTOCOL, VENDOR or TLV block
 *                      we're in. Block context changes in $INCLUDEs should
 *                      not affect the context of the including file.
 * @param[in] dir_name  Directory containing the dictionary we're loading.
 * @param[in] filename  we're parsing.
 * @param[in] src_file  The including file.
 * @param[in] src_line  Line on which the $INCLUDE or $NCLUDE- statement was found.
 * @return
 *      - 0 on success.
 *      - -1 on failure.
 */
static int _dict_from_file(dict_tokenize_ctx_t *dctx,
                           char const *dir_name, char const *filename,
                           char const *src_file, int src_line)
{
        static fr_dict_keyword_t const keywords[] = {
                { L("ALIAS"),                   { .parse = dict_read_process_alias } },
                { L("ATTRIBUTE"),               { .parse = dict_read_process_attribute } },
                { L("BEGIN-PROTOCOL"),          { .parse = dict_read_process_begin_protocol } },
                { L("BEGIN-VENDOR"),            { .parse = dict_read_process_begin_vendor } },
                { L("DEFINE"),                  { .parse = dict_read_process_define } },
                { L("END"),                     { .parse = dict_read_process_end } },
                { L("END-PROTOCOL"),            { .parse = dict_read_process_end_protocol } },
                { L("END-VENDOR"),              { .parse = dict_read_process_end_vendor } },
                { L("ENUM"),                    { .parse = dict_read_process_enum } },
                { L("FLAGS"),                   { .parse = dict_read_process_flags } },
                { L("MEMBER"),                  { .parse = dict_read_process_member } },
                { L("PROTOCOL"),                { .parse = dict_read_process_protocol, .begin = dict_begin_protocol }},
                { L("STRUCT"),                  { .parse = dict_read_process_struct } },
                { L("VALUE"),                   { .parse = dict_read_process_value } },
                { L("VENDOR"),                  { .parse = dict_read_process_vendor } },
        };
 
        FILE                    *fp;
        char                    dir[256], fn[256];
        char                    buf[256];
        char                    *p;
        int                     line = 0;
        bool                    was_member = false;
 
        struct stat             statbuf;
        char                    *argv[DICT_MAX_ARGV];
        int                     argc;
 
        /*
         *      Base flags are only set for the current file
         */
        fr_dict_attr_flags_t    base_flags = {};
 
        if (!fr_cond_assert(!dctx->dict->root || dctx->stack[dctx->stack_depth].da)) return -1;
 
        if ((strlen(dir_name) + 3 + strlen(filename)) > sizeof(dir)) {
                fr_strerror_printf_push("%s: Filename name too long", "Error reading dictionary");
                return -1;
        }
 
        /*
         *      If it's an absolute dir, forget the parent dir,
         *      and remember the new one.
         *
         *      If it's a relative dir, tack on the current filename
         *      to the parent dir.  And use that.
         */
        if (!FR_DIR_IS_RELATIVE(filename)) {
                strlcpy(dir, filename, sizeof(dir));
                p = strrchr(dir, FR_DIR_SEP);
                if (p) {
                        p[1] = '\0';
                } else {
                        strlcat(dir, "/", sizeof(dir));
                }
 
                strlcpy(fn, filename, sizeof(fn));
        } else {
                strlcpy(dir, dir_name, sizeof(dir));
                p = strrchr(dir, FR_DIR_SEP);
                if (p) {
                        if (p[1]) strlcat(dir, "/", sizeof(dir));
                } else {
                        strlcat(dir, "/", sizeof(dir));
                }
                strlcat(dir, filename, sizeof(dir));
                p = strrchr(dir, FR_DIR_SEP);
                if (p) {
                        p[1] = '\0';
                } else {
                        strlcat(dir, "/", sizeof(dir));
                }
 
                p = strrchr(filename, FR_DIR_SEP);
                if (p) {
                        snprintf(fn, sizeof(fn), "%s%s", dir, p);
                } else {
                        snprintf(fn, sizeof(fn), "%s%s", dir, filename);
                }
        }
 
        /*
         *      See if we have already loaded this filename.  If so, suppress it.
         */
#ifndef NDEBUG
        if (unlikely(dict_filename_loaded(dctx->dict, fn))) {
                fr_strerror_printf("ERROR - we have a recursive $INCLUDE or load of dictionary %s", fn);
                return -1;
        }
#endif
 
        if ((fp = fopen(fn, "r")) == NULL) {
                if (!src_file) {
                        fr_strerror_printf_push("Couldn't open dictionary %s: %s", fr_syserror(errno), fn);
                } else {
                        fr_strerror_printf_push("Error reading dictionary: %s[%d]: Couldn't open dictionary '%s': %s",
                                                fr_cwd_strip(src_file), src_line, fn,
                                                fr_syserror(errno));
                }
                return -2;
        }
 
        /*
         *      If fopen works, this works.
         */
        if (fstat(fileno(fp), &statbuf) < 0) {
                fr_strerror_printf_push("Failed stating dictionary \"%s\" - %s", fn, fr_syserror(errno));
 
        perm_error:
                fclose(fp);
                return -1;
        }
 
        if (!S_ISREG(statbuf.st_mode)) {
                fr_strerror_printf_push("Dictionary is not a regular file: %s", fn);
                goto perm_error;
        }
 
        /*
         *      Globally writable dictionaries means that users can control
         *      the server configuration with little difficulty.
         */
#ifdef S_IWOTH
        if (dict_gctx->perm_check && ((statbuf.st_mode & S_IWOTH) != 0)) {
                fr_strerror_printf_push("Dictionary is globally writable: %s. "
                                        "Refusing to start due to insecure configuration", fn);
                goto perm_error;
        }
#endif
 
        /*
         *      Now that we've opened the file, copy the filename into the dictionary and add it to the ctx
         *      This string is safe to assign to the filename pointer in any attributes added beneath the
         *      dictionary.
         */
        if (unlikely(dict_filename_add(&CURRENT_FILENAME(dctx), dctx->dict, fn) < 0)) {
                fr_strerror_const("Out of memory");
                goto perm_error;
        }
 
        while (fgets(buf, sizeof(buf), fp) != NULL) {
                bool do_begin = false;
                fr_dict_keyword_parser_t const  *parser;
                char **argv_p = argv;
 
                dctx->stack[dctx->stack_depth].line = ++line;
 
                switch (buf[0]) {
                case '#':
                case '\0':
                case '\n':
                case '\r':
                        continue;
                }
 
                /*
                 *  Comment characters should NOT be appearing anywhere but
                 *  as start of a comment;
                 */
                p = strchr(buf, '#');
                if (p) *p = '\0';
 
                argc = fr_dict_str_to_argv(buf, argv, DICT_MAX_ARGV);
                if (argc == 0) continue;
 
                if (argc == 1) {
                        fr_strerror_const("Invalid entry");
 
                error:
                        fr_strerror_printf_push("Failed parsing dictionary at %s[%d]", fr_cwd_strip(fn), line);
                        fclose(fp);
                        return -1;
                }
 
                /*
                 *      Special prefix for "beginnable" keywords.
                 *      These are keywords that can automatically change
                 *      the context of subsequent definitions if they're
                 *      prefixed with a BEGIN keyword.
                 */
                if (strcasecmp(argv_p[0], "BEGIN") == 0) {
                        do_begin = true;
                        argv_p++;
                        argc--;
                }
 
                if (fr_dict_keyword(&parser, keywords, NUM_ELEMENTS(keywords), argv_p[0], NULL)) {
                        if (do_begin && !parser->begin) {
                                fr_strerror_printf_push("BEGIN not allowed with %s", argv_p[0]);
                                goto error;
                        }
 
                        /*
                         *      Note: This is broken.  It won't apply correctly to deferred
                         *      definitions of attributes we need some kind of proper
                         *      finalisation API.
                         */
                        if (parser->parse == dict_read_process_member) {
                                was_member = true;
                        } else if (was_member) {
                                if (unlikely(dict_struct_finalise(dctx) < 0)) goto error;
                                was_member = false;
                        }
                        if (unlikely(parser->parse(dctx, argv_p + 1 , argc - 1, &base_flags) < 0)) goto error;
 
                        /*
                         *      We've processed the definition, now enter the section
                         */
                        if (do_begin && unlikely(parser->begin(dctx) < 0)) goto error;
                        continue;
                }
 
                /*
                 *      It's a naked BEGIN keyword
                 */
                if (do_begin) {
                        if (unlikely(dict_read_process_begin(dctx, argv_p, argc, &base_flags) < 0)) goto error;
                        continue;
                }
 
                /*
                 *      See if we need to import another dictionary.
                 */
                if (strncasecmp(argv_p[0], "$INCLUDE", 8) == 0) {
                        /*
                         *      Included files operate on a copy of the context.
                         *
                         *      This copy means that they inherit the
                         *      current context, including parents,
                         *      TLVs, etc.  But if the included file
                         *      leaves a "dangling" TLV or "last
                         *      attribute", then it won't affect the
                         *      parent.
                         */
                        if (dict_read_process_include(dctx, argv_p, argc, dir) < 0) goto error;
                        continue;
                } /* $INCLUDE */
 
                /*
                 *      Any other string: We don't recognize it.
                 */
                fr_strerror_printf_push("Invalid keyword '%s'", argv_p[0]);
                goto error;
        }
 
        if (was_member && unlikely(dict_struct_finalise(dctx) < 0)) goto error;
 
        /*
         *      Note that we do NOT walk back up the stack to check
         *      for missing END-FOO to match BEGIN-FOO.  The context
         *      was copied from the parent, so there are guaranteed to
         *      be missing things.
         */
        fclose(fp);
 
 
        return 0;
}
 
static int dict_from_file(fr_dict_t *dict,
                          char const *dir_name, char const *filename,
                          char const *src_file, int src_line)
{
        int ret;
        dict_tokenize_ctx_t dctx;
 
        memset(&dctx, 0, sizeof(dctx));
        dctx.dict = dict;
        dict_fixup_init(NULL, &dctx.fixup);
        dctx.stack[0].dict = dict;
        dctx.stack[0].da = dict->root;
        dctx.stack[0].nest = NEST_ROOT;
 
        ret = _dict_from_file(&dctx, dir_name, filename, src_file, src_line);
        if (ret < 0) {
                talloc_free(dctx.fixup.pool);
                return ret;
        }
 
        /*
         *      Applies  to any attributes added to the *internal*
         *      dictionary.
         *
         *      Fixups should have been applied already to any protocol
         *      dictionaries.
         */
        return dict_finalise(&dctx);
}
 
/** (Re-)Initialize the special internal dictionary
 *
 * This dictionary has additional programmatically generated attributes added to it,
 * and is checked in addition to the protocol specific dictionaries.
 *
 * @note The dictionary pointer returned in out must have its reference counter
 *       decremented with #fr_dict_free when no longer used.
 *
 * @param[out] out              Where to write pointer to the internal dictionary.
 * @param[in] dict_subdir       name of the internal dictionary dir (may be NULL).
 * @param[in] dependent         Either C src file, or another dictionary.
 * @return
 *      - 0 on success.
 *      - -1 on failure.
 */
int fr_dict_internal_afrom_file(fr_dict_t **out, char const *dict_subdir, char const *dependent)
{
        fr_dict_t               *dict;
        char                    *dict_path = NULL;
        size_t                  i;
        fr_dict_attr_flags_t    flags = { .internal = true };
        char                    *type_name;
        fr_dict_attr_t          *cast_base;
        fr_value_box_t          box = FR_VALUE_BOX_INITIALISER_NULL(box);
 
        if (unlikely(!dict_gctx)) {
                fr_strerror_const("fr_dict_global_ctx_init() must be called before loading dictionary files");
                return -1;
        }
 
        /*
         *      Increase the reference count of the internal dictionary.
         */
        if (dict_gctx->internal) {
                 dict_dependent_add(dict_gctx->internal, dependent);
                 *out = dict_gctx->internal;
                 return 0;
        }
 
        dict_path = dict_subdir ?
                    talloc_asprintf(NULL, "%s%c%s", fr_dict_global_ctx_dir(), FR_DIR_SEP, dict_subdir) :
                    talloc_strdup(NULL, fr_dict_global_ctx_dir());
 
        fr_strerror_clear();    /* Ensure we don't report spurious errors */
 
        dict = dict_alloc(dict_gctx);
        if (!dict) {
        error:
                if (!dict_gctx->internal) talloc_free(dict);
                talloc_free(dict_path);
                return -1;
        }
 
        /*
         *      Set the root name of the dictionary
         */
        if (dict_root_set(dict, "internal", 0) < 0) goto error;
 
        if (dict_path && dict_from_file(dict, dict_path, FR_DICTIONARY_FILE, NULL, 0) < 0) goto error;
 
        TALLOC_FREE(dict_path);
 
        dict_dependent_add(dict, dependent);
 
        if (!dict_gctx->internal) {
                dict_gctx->internal = dict;
                dict_dependent_add(dict, "global");
        }
 
        /*
         *      Try to load libfreeradius-internal, too.  If that
         *      fails (i.e. fuzzers???), ignore it.
         */
        (void) dict_dlopen(dict, "internal");
 
        cast_base = dict_attr_child_by_num(dict->root, FR_CAST_BASE);
        if (!cast_base) {
                fr_strerror_printf("Failed to find 'Cast-Base' in internal dictionary");
                goto error;
        }
 
        fr_assert(cast_base->type == FR_TYPE_UINT8);
        fr_value_box_init(&box, FR_TYPE_UINT8, NULL, false);
 
        /*
         *      Add cast attributes.  We do it this way,
         *      so cast attributes get added automatically for new types.
         *
         *      We manually add the attributes to the dictionary, and bypass
         *      fr_dict_attr_add(), because we know what we're doing, and
         *      that function does too many checks.
         */
        for (i = 0; i < fr_type_table_len; i++) {
                fr_dict_attr_t                  *n;
                fr_table_num_ordered_t const    *p = &fr_type_table[i];
 
                switch (p->value) {
                case FR_TYPE_NULL:      /* Can't cast to NULL */
                case FR_TYPE_VENDOR:    /* Vendors can't exist in dictionaries as attributes */
                        continue;
                }
 
                type_name = talloc_typed_asprintf(NULL, "Tmp-Cast-%s", p->name.str);
 
                n = dict_attr_alloc(dict->pool, dict->root, type_name,
                                    FR_CAST_BASE + p->value, p->value, &(dict_attr_args_t){ .flags = &flags});
                if (!n) {
                        talloc_free(type_name);
                        goto error;
                }
 
                if (dict_attr_add_to_namespace(dict->root, n) < 0) {
                        fr_strerror_printf_push("Failed inserting '%s' into internal dictionary", type_name);
                        talloc_free(type_name);
                        goto error;
                }
 
                talloc_free(type_name);
 
                /*
                 *      Set up parenting for the attribute.
                 */
                if (dict_attr_child_add(dict->root, n) < 0) goto error;
 
                /*
                 *      Add the enum, too.
                 */
                box.vb_uint8 = p->value;
                if (dict_attr_enum_add_name(cast_base, p->name.str, &box, false, false, NULL) < 0) {
                        fr_strerror_printf_push("Failed adding '%s' as a VALUE into internal dictionary", p->name.str);
                        goto error;
                }
        }
 
        *out = dict;
 
        return 0;
}
 
/** (Re)-initialize a protocol dictionary
 *
 * Initialize the directory, then fix the attr number of all attributes.
 *
 * @param[out] out              Where to write a pointer to the new dictionary.  Will free existing
 *                              dictionary if files have changed and *out is not NULL.
 * @param[in] proto_name        that we're loading the dictionary for.
 * @param[in] proto_dir         Explicitly set where to hunt for the dictionary files.  May be NULL.
 * @param[in] dependent         Either C src file, or another dictionary.
 * @return
 *      - 0 on success.
 *      - -1 on failure.
 */
int fr_dict_protocol_afrom_file(fr_dict_t **out, char const *proto_name, char const *proto_dir, char const *dependent)
{
        char            *dict_dir = NULL;
        fr_dict_t       *dict;
        bool            added = false;
 
        *out = NULL;
 
        if (unlikely(!dict_gctx)) {
                fr_strerror_const("fr_dict_global_ctx_init() must be called before loading dictionary files");
                return -1;
        }
 
        if (unlikely(!dict_gctx->internal)) {
                fr_strerror_const("Internal dictionary must be initialised before loading protocol dictionaries");
                return -1;
        }
 
        /*
         *      Increment the reference count if the dictionary
         *      has already been loaded and return that.
         */
        dict = dict_by_protocol_name(proto_name);
        if (dict) {
                /*
                 *      If we're in the middle of loading this dictionary, then the only way we get back here
                 *      is via a circular reference.  So we catch that, and drop the circular dependency.
                 *
                 *      When we have A->B->A, it means that we don't need to track B->A, because we track
                 *      A->B.  And if A is freed, then B is freed.
                 */
                added = true;
                dict_dependent_add(dict, dependent);
 
                /*
                 *      But we only return a pre-existing dict if _this function_ has loaded it.
                 */
                if (dict->loaded) {
                        *out = dict;
                        return 0;
                }
 
                /*
                 *      Set the flag to true _before_ loading the file.  That prevents recursion.
                 */
                dict->loaded = true;
        }
 
        if (!proto_dir) {
                dict_dir = talloc_asprintf(NULL, "%s%c%s", fr_dict_global_ctx_dir(), FR_DIR_SEP, proto_name);
        } else {
                dict_dir = talloc_asprintf(NULL, "%s%c%s", fr_dict_global_ctx_dir(), FR_DIR_SEP, proto_dir);
        }
 
        fr_strerror_clear();    /* Ensure we don't report spurious errors */
 
        /*
         *      Start in the context of the internal dictionary,
         *      and switch to the context of a protocol dictionary
         *      when we hit a BEGIN-PROTOCOL line.
         *
         *      This allows a single file to provide definitions
         *      for multiple protocols, which'll probably be useful
         *      at some point.
         */
        if (dict_from_file(dict_gctx->internal, dict_dir, FR_DICTIONARY_FILE, NULL, 0) < 0) {
        error:
                if (dict) dict->loading = false;
                talloc_free(dict_dir);
                return -1;
        }
 
        /*
         *      Check the dictionary actually defined the protocol
         */
        dict = dict_by_protocol_name(proto_name);
        if (!dict) {
                fr_strerror_printf("Dictionary \"%s\" missing \"BEGIN-PROTOCOL %s\" declaration", dict_dir, proto_name);
                goto error;
        }
 
        /*
         *      Initialize the library.
         */
        dict->loaded = true;
        if (dict->proto && dict->proto->init) {
                if (dict->proto->init() < 0) goto error;
        }
        dict->loading = false;
 
        talloc_free(dict_dir);
 
        if (!added) dict_dependent_add(dict, dependent);
 
        *out = dict;
 
        return 0;
}
 
/* Alloc a new root dictionary attribute
 *
 * @note Must only be called once per dictionary.
 *
 * @param[in] proto_name        that we're loading the dictionary for.
 * @param[in] proto_number      The artificial (or IANA allocated) number for the protocol.
 * @return
 *      - A pointer to the new dict context on success.
 *      - NULL on failure.
 */
fr_dict_t *fr_dict_alloc(char const *proto_name, unsigned int proto_number)
{
        fr_dict_t       *dict;
 
        if (unlikely(!dict_gctx)) {
                fr_strerror_printf("fr_dict_global_ctx_init() must be called before loading dictionary files");
                return NULL;
        }
 
        /*
         *      Alloc dict instance.
         */
        dict = dict_alloc(dict_gctx);
        if (!dict) return NULL;
 
        /*
         *      Set the root name of the dictionary
         */
        if (dict_root_set(dict, proto_name, proto_number) < 0) {
                talloc_free(dict);
                return NULL;
        }
 
        return dict;
}
 
/** Read supplementary attribute definitions into an existing dictionary
 *
 * @param[in] dict      Existing dictionary.
 * @param[in] dir       dictionary is located in.
 * @param[in] filename  of the dictionary.
 * @return
 *      - 0 on success.
 *      - -1 on failure.
 */
int fr_dict_read(fr_dict_t *dict, char const *dir, char const *filename)
{
        INTERNAL_IF_NULL(dict, -1);
 
        if (unlikely(dict->read_only)) {
                fr_strerror_printf("%s dictionary has been marked as read only", fr_dict_root(dict)->name);
                return -1;
        }
 
        if (!dict->vendors_by_name) {
                fr_strerror_printf("%s: Must initialise dictionary before calling fr_dict_read()", __FUNCTION__);
                return -1;
        }
 
        return dict_from_file(dict, dir, filename, NULL, 0);
}
 
/*
 *      External API for testing
 */
int fr_dict_parse_str(fr_dict_t *dict, char *buf, fr_dict_attr_t const *parent)
{
        int                     argc;
        char                    *argv[DICT_MAX_ARGV];
        int                     ret;
        fr_dict_attr_flags_t    base_flags;
        dict_tokenize_ctx_t     dctx;
 
        INTERNAL_IF_NULL(dict, -1);
 
        argc = fr_dict_str_to_argv(buf, argv, DICT_MAX_ARGV);
        if (argc == 0) return 0;
 
 
        memset(&dctx, 0, sizeof(dctx));
        dctx.dict = dict;
        dctx.stack[0].dict = dict;
        dctx.stack[0].da = dict->root;
        dctx.stack[0].nest = NEST_ROOT;
 
        if (dict_fixup_init(NULL, &dctx.fixup) < 0) return -1;
 
        if (strcasecmp(argv[0], "VALUE") == 0) {
                if (argc < 4) {
                        fr_strerror_printf("VALUE needs at least 4 arguments, got %i", argc);
                error:
                        TALLOC_FREE(dctx.fixup.pool);
                        return -1;
                }
 
                if (!fr_dict_attr_by_oid(NULL, fr_dict_root(dict), argv[1])) {
                        fr_strerror_printf("Attribute '%s' does not exist in dictionary \"%s\"",
                                           argv[1], dict->root->name);
                        goto error;
                }
                ret = dict_read_process_value(&dctx, argv + 1, argc - 1, &base_flags);
                if (ret < 0) goto error;
 
        } else if (strcasecmp(argv[0], "ATTRIBUTE") == 0) {
                if (parent && (parent != dict->root)) dctx.stack[++dctx.stack_depth].da = parent;
 
                memset(&base_flags, 0, sizeof(base_flags));
 
                ret = dict_read_process_attribute(&dctx,
                                                  argv + 1, argc - 1, &base_flags);
                if (ret < 0) goto error;
        } else if (strcasecmp(argv[0], "VENDOR") == 0) {
                ret = dict_read_process_vendor(&dctx, argv + 1, argc - 1, &base_flags);
                if (ret < 0) goto error;
        } else {
                fr_strerror_printf("Invalid input '%s'", argv[0]);
                goto error;
        }
 
        return dict_finalise(&dctx);
}