util/keyval.c - qemu - Git at Google

 /*
  * Parsing KEY=VALUE,... strings
  *
  * Copyright (C) 2017 Red Hat Inc.
  *
  * Authors:
  *  Markus Armbruster <armbru@redhat.com>,
  *
  * This work is licensed under the terms of the GNU GPL, version 2 or later.
  * See the COPYING file in the top-level directory.
  */

 /*
  * KEY=VALUE,... syntax:
  *
  *   key-vals     = [ key-val { ',' key-val } [ ',' ] ]
  *   key-val      = key '=' val | help
  *   key          = key-fragment { '.' key-fragment }
  *   key-fragment = qapi-name | index
  *   qapi-name    = '__' / [a-z0-9.-]+ / '_' / [A-Za-z][A-Za-z0-9_-]* /
  *   index        = / [0-9]+ /
  *   val          = { / [^,]+ / | ',,' }
  *   help         = 'help' | '?'
  *
  * Semantics defined by reduction to JSON:
  *
  *   key-vals specifies a JSON object, i.e. a tree whose root is an
  *   object, inner nodes other than the root are objects or arrays,
  *   and leaves are strings.
  *
  *   Each key-val = key-fragment '.' ... '=' val specifies a path from
  *   root to a leaf (left of '='), and the leaf's value (right of
  *   '=').
  *
  *   A path from the root is defined recursively:
  *       L '.' key-fragment is a child of the node denoted by path L
  *       key-fragment is a child of the tree root
  *   If key-fragment is numeric, the parent is an array and the child
  *   is its key-fragment-th member, counting from zero.
  *   Else, the parent is an object, and the child is its member named
  *   key-fragment.
  *
  *   This constrains inner nodes to be either array or object.  The
  *   constraints must be satisfiable.  Counter-example: a.b=1,a=2 is
  *   not, because root.a must be an object to satisfy a.b=1 and a
  *   string to satisfy a=2.
  *
  *   Array subscripts can occur in any order, but the set of
  *   subscripts must not have gaps.  For instance, a.1=v is not okay,
  *   because root.a[0] is missing.
  *
  *   If multiple key-val denote the same leaf, the last one determines
  *   the value.
  *
  * Key-fragments must be valid QAPI names or consist only of decimal
  * digits.
  *
  * The length of any key-fragment must be between 1 and 127.
  *
  * If any key-val is help, the object is to be treated as a help
  * request.
  *
  * Design flaw: there is no way to denote an empty array or non-root
  * object.  While interpreting "key absent" as empty seems natural
  * (removing a key-val from the input string removes the member when
  * there are more, so why not when it's the last), it doesn't work:
  * "key absent" already means "optional object/array absent", which
  * isn't the same as "empty object/array present".
  *
  * Design flaw: scalar values can only be strings; there is no way to
  * denote numbers, true, false or null.  The special QObject input
  * visitor returned by qobject_input_visitor_new_keyval() mostly hides
  * this by automatically converting strings to the type the visitor
  * expects.  Breaks down for type 'any', where the visitor's
  * expectation isn't clear.  Code visiting 'any' needs to do the
  * conversion itself, but only when using this keyval visitor.
  * Awkward.  Note that we carefully restrict alternate types to avoid
  * similar ambiguity.
  *
  * Alternative syntax for use with an implied key:
  *
  *   key-vals     = [ key-val-1st { ',' key-val } [ ',' ] ]
  *   key-val-1st  = val-no-key | key-val
  *   val-no-key   = / [^=,]+ / - help
  *
  * where val-no-key is syntactic sugar for implied-key=val-no-key.
  *
  * Note that you can't use the sugared form when the value contains
  * '=' or ','.
  */

 #include "qemu/osdep.h"
 #include "qapi/error.h"
 #include "qapi/qmp/qdict.h"
 #include "qapi/qmp/qlist.h"
 #include "qapi/qmp/qstring.h"
 #include "qemu/cutils.h"
 #include "qemu/keyval.h"
 #include "qemu/help_option.h"

 /*
  * Convert @key to a list index.
  * Convert all leading decimal digits to a (non-negative) number,
  * capped at INT_MAX.
  * If @end is non-null, assign a pointer to the first character after
  * the number to *@end.
  * Else, fail if any characters follow.
  * On success, return the converted number.
  * On failure, return a negative value.
  * Note: since only digits are converted, no two keys can map to the
  * same number, except by overflow to INT_MAX.
  */
 static int key_to_index(const char *key, const char **end)
 {
     int ret;
     unsigned long index;

     if (*key < '0' || *key > '9') {
         return -EINVAL;
     }
     ret = qemu_strtoul(key, end, 10, &index);
     if (ret) {
         return ret == -ERANGE ? INT_MAX : ret;
     }
     return index <= INT_MAX ? index : INT_MAX;
 }

 /*
  * Ensure @cur maps @key_in_cur the right way.
  * If @value is null, it needs to map to a QDict, else to this
  * QString.
  * If @cur doesn't have @key_in_cur, put an empty QDict or @value,
  * respectively.
  * Else, if it needs to map to a QDict, and already does, do nothing.
  * Else, if it needs to map to this QString, and already maps to a
  * QString, replace it by @value.
  * Else, fail because we have conflicting needs on how to map
  * @key_in_cur.
  * In any case, take over the reference to @value, i.e. if the caller
  * wants to hold on to a reference, it needs to qobject_ref().
  * Use @key up to @key_cursor to identify the key in error messages.
  * On success, return the mapped value.
  * On failure, store an error through @errp and return NULL.
  */
 static QObject *keyval_parse_put(QDict *cur,
                                  const char *key_in_cur, QString *value,
                                  const char *key, const char *key_cursor,
                                  Error **errp)
 {
     QObject *old, *new;

     old = qdict_get(cur, key_in_cur);
     if (old) {
         if (qobject_type(old) != (value ? QTYPE_QSTRING : QTYPE_QDICT)) {
             error_setg(errp, "Parameters '%.*s.*' used inconsistently",
                        (int)(key_cursor - key), key);
             qobject_unref(value);
             return NULL;
         }
         if (!value) {
             return old;         /* already QDict, do nothing */
         }
         new = QOBJECT(value);   /* replacement */
     } else {
         new = value ? QOBJECT(value) : QOBJECT(qdict_new());
     }
     qdict_put_obj(cur, key_in_cur, new);
     return new;
 }

 /*
  * Parse one parameter from @params.
  *
  * If we're looking at KEY=VALUE, store result in @qdict.
  * The first fragment of KEY applies to @qdict.  Subsequent fragments
  * apply to nested QDicts, which are created on demand.  @implied_key
  * is as in keyval_parse().
  *
  * If we're looking at "help" or "?", set *help to true.
  *
  * On success, return a pointer to the next parameter, or else to '\0'.
  * On failure, return NULL.
  */
 static const char *keyval_parse_one(QDict *qdict, const char *params,
                                     const char *implied_key, bool *help,
                                     Error **errp)
 {
     const char *key, *key_end, *val_end, *s, *end;
     size_t len;
     char key_in_cur[128];
     QDict *cur;
     int ret;
     QObject *next;
     GString *val;

     key = params;
     val_end = NULL;
     len = strcspn(params, "=,");
     if (len && key[len] != '=') {
         if (starts_with_help_option(key) == len) {
             *help = true;
             s = key + len;
             if (*s == ',') {
                 s++;
             }
             return s;
         }
         if (implied_key) {
             /* Desugar implied key */
             key = implied_key;
             val_end = params + len;
             len = strlen(implied_key);
         }
     }
     key_end = key + len;

     /*
      * Loop over key fragments: @s points to current fragment, it
      * applies to @cur.  @key_in_cur[] holds the previous fragment.
      */
     cur = qdict;
     s = key;
     for (;;) {
         /* Want a key index (unless it's first) or a QAPI name */
         if (s != key && key_to_index(s, &end) >= 0) {
             len = end - s;
         } else {
             ret = parse_qapi_name(s, false);
             len = ret < 0 ? 0 : ret;
         }
         assert(s + len <= key_end);
         if (!len || (s + len < key_end && s[len] != '.')) {
             assert(key != implied_key);
             error_setg(errp, "Invalid parameter '%.*s'",
                        (int)(key_end - key), key);
             return NULL;
         }
         if (len >= sizeof(key_in_cur)) {
             assert(key != implied_key);
             error_setg(errp, "Parameter%s '%.*s' is too long",
                        s != key || s + len != key_end ? " fragment" : "",
                        (int)len, s);
             return NULL;
         }

         if (s != key) {
             next = keyval_parse_put(cur, key_in_cur, NULL,
                                     key, s - 1, errp);
             if (!next) {
                 return NULL;
             }
             cur = qobject_to(QDict, next);
             assert(cur);
         }

         memcpy(key_in_cur, s, len);
         key_in_cur[len] = 0;
         s += len;

         if (*s != '.') {
             break;
         }
         s++;
     }

     if (key == implied_key) {
         assert(!*s);
         val = g_string_new_len(params, val_end - params);
         s = val_end;
         if (*s == ',') {
             s++;
         }
     } else {
         if (*s != '=') {
             error_setg(errp, "Expected '=' after parameter '%.*s'",
                        (int)(s - key), key);
             return NULL;
         }
         s++;

         val = g_string_new(NULL);
         for (;;) {
             if (!*s) {
                 break;
             } else if (*s == ',') {
                 s++;
                 if (*s != ',') {
                     break;
                 }
             }
             g_string_append_c(val, *s++);
         }
     }

     if (!keyval_parse_put(cur, key_in_cur, qstring_from_gstring(val),
                           key, key_end, errp)) {
         return NULL;
     }
     return s;
 }

 static char *reassemble_key(GSList *key)
 {
     GString *s = g_string_new("");
     GSList *p;

     for (p = key; p; p = p->next) {
         g_string_prepend_c(s, '.');
         g_string_prepend(s, (char *)p->data);
     }

     return g_string_free(s, FALSE);
 }

 /*
  * Recursive worker for keyval_merge.
  *
  * @str is the path that led to the * current dictionary (to be used for
  * error messages).  It is modified internally but restored before the
  * function returns.
  */
 static void keyval_do_merge(QDict *dest, const QDict *merged, GString *str, Error **errp)
 {
     size_t save_len = str->len;
     const QDictEntry *ent;
     QObject *old_value;

     for (ent = qdict_first(merged); ent; ent = qdict_next(merged, ent)) {
         old_value = qdict_get(dest, ent->key);
         if (old_value) {
             if (qobject_type(old_value) != qobject_type(ent->value)) {
                 error_setg(errp, "Parameter '%s%s' used inconsistently",
                            str->str, ent->key);
                 return;
             } else if (qobject_type(ent->value) == QTYPE_QDICT) {
                 /* Merge sub-dictionaries.  */
                 g_string_append(str, ent->key);
                 g_string_append_c(str, '.');
                 keyval_do_merge(qobject_to(QDict, old_value),
                                 qobject_to(QDict, ent->value),
                                 str, errp);
                 g_string_truncate(str, save_len);
                 continue;
             } else if (qobject_type(ent->value) == QTYPE_QLIST) {
                 /* Append to old list.  */
                 QList *old = qobject_to(QList, old_value);
                 QList *new = qobject_to(QList, ent->value);
                 const QListEntry *item;
                 QLIST_FOREACH_ENTRY(new, item) {
                     qobject_ref(item->value);
                     qlist_append_obj(old, item->value);
                 }
                 continue;
             } else {
                 assert(qobject_type(ent->value) == QTYPE_QSTRING);
             }
         }

         qobject_ref(ent->value);
         qdict_put_obj(dest, ent->key, ent->value);
     }
 }

 /* Merge the @merged dictionary into @dest.
  *
  * The dictionaries are expected to be returned by the keyval parser, and
  * therefore the only expected scalar type is the string.  In case the same
  * path is present in both @dest and @merged, the semantics are as follows:
  *
  * - lists are concatenated
  *
  * - dictionaries are merged recursively
  *
  * - for scalar values, @merged wins
  *
  * In case an error is reported, @dest may already have been modified.
  *
  * This function can be used to implement semantics analogous to QemuOpts's
  * .merge_lists = true case, or to implement -set for options backed by QDicts.
  *
  * Note: while QemuOpts is commonly used so that repeated keys overwrite
  * ("last one wins"), it can also be used so that repeated keys build up
  * a list. keyval_merge() can only be used when the options' semantics are
  * the former, not the latter.
  */
 void keyval_merge(QDict *dest, const QDict *merged, Error **errp)
 {
     GString *str;

     str = g_string_new("");
     keyval_do_merge(dest, merged, str, errp);
     g_string_free(str, TRUE);
 }

 /*
  * Listify @cur recursively.
  * Replace QDicts whose keys are all valid list indexes by QLists.
  * @key_of_cur is the list of key fragments leading up to @cur.
  * On success, return either @cur or its replacement.
  * On failure, store an error through @errp and return NULL.
  */
 static QObject *keyval_listify(QDict *cur, GSList *key_of_cur, Error **errp)
 {
     GSList key_node;
     bool has_index, has_member;
     const QDictEntry *ent;
     QDict *qdict;
     QObject *val;
     char *key;
     size_t nelt;
     QObject **elt;
     int index, max_index, i;
     QList *list;

     key_node.next = key_of_cur;

     /*
      * Recursively listify @cur's members, and figure out whether @cur
      * itself is to be listified.
      */
     has_index = false;
     has_member = false;
     for (ent = qdict_first(cur); ent; ent = qdict_next(cur, ent)) {
         if (key_to_index(ent->key, NULL) >= 0) {
             has_index = true;
         } else {
             has_member = true;
         }

         qdict = qobject_to(QDict, ent->value);
         if (!qdict) {
             continue;
         }

         key_node.data = ent->key;
         val = keyval_listify(qdict, &key_node, errp);
         if (!val) {
             return NULL;
         }
         if (val != ent->value) {
             qdict_put_obj(cur, ent->key, val);
         }
     }

     if (has_index && has_member) {
         key = reassemble_key(key_of_cur);
         error_setg(errp, "Parameters '%s*' used inconsistently", key);
         g_free(key);
         return NULL;
     }
     if (!has_index) {
         return QOBJECT(cur);
     }

     /* Copy @cur's values to @elt[] */
     nelt = qdict_size(cur) + 1; /* one extra, for use as sentinel */
     elt = g_new0(QObject *, nelt);
     max_index = -1;
     for (ent = qdict_first(cur); ent; ent = qdict_next(cur, ent)) {
         index = key_to_index(ent->key, NULL);
         assert(index >= 0);
         if (index > max_index) {
             max_index = index;
         }
         /*
          * We iterate @nelt times.  If we get one exceeding @nelt
          * here, we will put less than @nelt values into @elt[],
          * triggering the error in the next loop.
          */
         if ((size_t)index >= nelt - 1) {
             continue;
         }
         /* Even though dict keys are distinct, indexes need not be */
         elt[index] = ent->value;
     }

     /*
      * Make a list from @elt[], reporting the first missing element,
      * if any.
      * If we dropped an index >= nelt in the previous loop, this loop
      * will run into the sentinel and report index @nelt missing.
      */
     list = qlist_new();
     assert(!elt[nelt-1]);       /* need the sentinel to be null */
     for (i = 0; i < MIN(nelt, max_index + 1); i++) {
         if (!elt[i]) {
             key = reassemble_key(key_of_cur);
             error_setg(errp, "Parameter '%s%d' missing", key, i);
             g_free(key);
             g_free(elt);
             qobject_unref(list);
             return NULL;
         }
         qobject_ref(elt[i]);
         qlist_append_obj(list, elt[i]);
     }

     g_free(elt);
     return QOBJECT(list);
 }

 /*
  * Parse @params in QEMU's traditional KEY=VALUE,... syntax.
  *
  * If @implied_key, the first KEY= can be omitted.  @implied_key is
  * implied then, and VALUE can't be empty or contain ',' or '='.
  *
  * A parameter "help" or "?" without a value isn't added to the
  * resulting dictionary, but instead is interpreted as help request.
  * All other options are parsed and returned normally so that context
  * specific help can be printed.
  *
  * If @p_help is not NULL, store whether help is requested there.
  * If @p_help is NULL and help is requested, fail.
  *
  * On success, return @dict, now filled with the parsed keys and values.
  *
  * On failure, store an error through @errp and return NULL.  Any keys
  * and values parsed so far will be in @dict nevertheless.
  */
 QDict *keyval_parse_into(QDict *qdict, const char *params, const char *implied_key,
                          bool *p_help, Error **errp)
 {
     QObject *listified;
     const char *s;
     bool help = false;

     s = params;
     while (*s) {
         s = keyval_parse_one(qdict, s, implied_key, &help, errp);
         if (!s) {
             return NULL;
         }
         implied_key = NULL;
     }

     if (p_help) {
         *p_help = help;
     } else if (help) {
         error_setg(errp, "Help is not available for this option");
         return NULL;
     }

     listified = keyval_listify(qdict, NULL, errp);
     if (!listified) {
         return NULL;
     }
     assert(listified == QOBJECT(qdict));
     return qdict;
 }

 /*
  * Parse @params in QEMU's traditional KEY=VALUE,... syntax.
  *
  * If @implied_key, the first KEY= can be omitted.  @implied_key is
  * implied then, and VALUE can't be empty or contain ',' or '='.
  *
  * A parameter "help" or "?" without a value isn't added to the
  * resulting dictionary, but instead is interpreted as help request.
  * All other options are parsed and returned normally so that context
  * specific help can be printed.
  *
  * If @p_help is not NULL, store whether help is requested there.
  * If @p_help is NULL and help is requested, fail.
  *
  * On success, return a dictionary of the parsed keys and values.
  * On failure, store an error through @errp and return NULL.
  */
 QDict *keyval_parse(const char *params, const char *implied_key,
                     bool *p_help, Error **errp)
 {
     QDict *qdict = qdict_new();
     QDict *ret = keyval_parse_into(qdict, params, implied_key, p_help, errp);

     if (!ret) {
         qobject_unref(qdict);
     }
     return ret;
 }
	/*
	* Parsing KEY=VALUE,... strings
	*
	* Copyright (C) 2017 Red Hat Inc.
	*
	* Authors:
	* Markus Armbruster <armbru@redhat.com>,
	*
	* This work is licensed under the terms of the GNU GPL, version 2 or later.
	* See the COPYING file in the top-level directory.
	*/

	/*
	* KEY=VALUE,... syntax:
	*
	* key-vals = [ key-val { ',' key-val } [ ',' ] ]
	* key-val = key '=' val \| help
	* key = key-fragment { '.' key-fragment }
	* key-fragment = qapi-name \| index
	* qapi-name = '__' / [a-z0-9.-]+ / '_' / [A-Za-z][A-Za-z0-9_-]* /
	* index = / [0-9]+ /
	* val = { / [^,]+ / \| ',,' }
	* help = 'help' \| '?'
	*
	* Semantics defined by reduction to JSON:
	*
	* key-vals specifies a JSON object, i.e. a tree whose root is an
	* object, inner nodes other than the root are objects or arrays,
	* and leaves are strings.
	*
	* Each key-val = key-fragment '.' ... '=' val specifies a path from
	* root to a leaf (left of '='), and the leaf's value (right of
	* '=').
	*
	* A path from the root is defined recursively:
	* L '.' key-fragment is a child of the node denoted by path L
	* key-fragment is a child of the tree root
	* If key-fragment is numeric, the parent is an array and the child
	* is its key-fragment-th member, counting from zero.
	* Else, the parent is an object, and the child is its member named
	* key-fragment.
	*
	* This constrains inner nodes to be either array or object. The
	* constraints must be satisfiable. Counter-example: a.b=1,a=2 is
	* not, because root.a must be an object to satisfy a.b=1 and a
	* string to satisfy a=2.
	*
	* Array subscripts can occur in any order, but the set of
	* subscripts must not have gaps. For instance, a.1=v is not okay,
	* because root.a[0] is missing.
	*
	* If multiple key-val denote the same leaf, the last one determines
	* the value.
	*
	* Key-fragments must be valid QAPI names or consist only of decimal
	* digits.
	*
	* The length of any key-fragment must be between 1 and 127.
	*
	* If any key-val is help, the object is to be treated as a help
	* request.
	*
	* Design flaw: there is no way to denote an empty array or non-root
	* object. While interpreting "key absent" as empty seems natural
	* (removing a key-val from the input string removes the member when
	* there are more, so why not when it's the last), it doesn't work:
	* "key absent" already means "optional object/array absent", which
	* isn't the same as "empty object/array present".
	*
	* Design flaw: scalar values can only be strings; there is no way to
	* denote numbers, true, false or null. The special QObject input
	* visitor returned by qobject_input_visitor_new_keyval() mostly hides
	* this by automatically converting strings to the type the visitor
	* expects. Breaks down for type 'any', where the visitor's
	* expectation isn't clear. Code visiting 'any' needs to do the
	* conversion itself, but only when using this keyval visitor.
	* Awkward. Note that we carefully restrict alternate types to avoid
	* similar ambiguity.
	*
	* Alternative syntax for use with an implied key:
	*
	* key-vals = [ key-val-1st { ',' key-val } [ ',' ] ]
	* key-val-1st = val-no-key \| key-val
	* val-no-key = / [^=,]+ / - help
	*
	* where val-no-key is syntactic sugar for implied-key=val-no-key.
	*
	* Note that you can't use the sugared form when the value contains
	* '=' or ','.
	*/

	#include "qemu/osdep.h"
	#include "qapi/error.h"
	#include "qapi/qmp/qdict.h"
	#include "qapi/qmp/qlist.h"
	#include "qapi/qmp/qstring.h"
	#include "qemu/cutils.h"
	#include "qemu/keyval.h"
	#include "qemu/help_option.h"

	/*
	* Convert @key to a list index.
	* Convert all leading decimal digits to a (non-negative) number,
	* capped at INT_MAX.
	* If @end is non-null, assign a pointer to the first character after
	* the number to *@end.
	* Else, fail if any characters follow.
	* On success, return the converted number.
	* On failure, return a negative value.
	* Note: since only digits are converted, no two keys can map to the
	* same number, except by overflow to INT_MAX.
	*/
	static int key_to_index(const char key, const char *end)
	{
	int ret;
	unsigned long index;

	if (key < '0' \|\| key > '9') {
	return -EINVAL;
	}
	ret = qemu_strtoul(key, end, 10, &index);
	if (ret) {
	return ret == -ERANGE ? INT_MAX : ret;
	}
	return index <= INT_MAX ? index : INT_MAX;
	}

	/*
	* Ensure @cur maps @key_in_cur the right way.
	* If @value is null, it needs to map to a QDict, else to this
	* QString.
	* If @cur doesn't have @key_in_cur, put an empty QDict or @value,
	* respectively.
	* Else, if it needs to map to a QDict, and already does, do nothing.
	* Else, if it needs to map to this QString, and already maps to a
	* QString, replace it by @value.
	* Else, fail because we have conflicting needs on how to map
	* @key_in_cur.
	* In any case, take over the reference to @value, i.e. if the caller
	* wants to hold on to a reference, it needs to qobject_ref().
	* Use @key up to @key_cursor to identify the key in error messages.
	* On success, return the mapped value.
	* On failure, store an error through @errp and return NULL.
	*/
	static QObject keyval_parse_put(QDict cur,
	const char key_in_cur, QString value,
	const char key, const char key_cursor,
	Error **errp)
	{
	QObject old, new;

	old = qdict_get(cur, key_in_cur);
	if (old) {
	if (qobject_type(old) != (value ? QTYPE_QSTRING : QTYPE_QDICT)) {
	error_setg(errp, "Parameters '%.s.' used inconsistently",
	(int)(key_cursor - key), key);
	qobject_unref(value);
	return NULL;
	}
	if (!value) {
	return old; /* already QDict, do nothing */
	}
	new = QOBJECT(value); /* replacement */
	} else {
	new = value ? QOBJECT(value) : QOBJECT(qdict_new());
	}
	qdict_put_obj(cur, key_in_cur, new);
	return new;
	}

	/*
	* Parse one parameter from @params.
	*
	* If we're looking at KEY=VALUE, store result in @qdict.
	* The first fragment of KEY applies to @qdict. Subsequent fragments
	* apply to nested QDicts, which are created on demand. @implied_key
	* is as in keyval_parse().
	*
	* If we're looking at "help" or "?", set *help to true.
	*
	* On success, return a pointer to the next parameter, or else to '\0'.
	* On failure, return NULL.
	*/
	static const char keyval_parse_one(QDict qdict, const char *params,
	const char implied_key, bool help,
	Error **errp)
	{
	const char key, key_end, val_end, s, *end;
	size_t len;
	char key_in_cur[128];
	QDict *cur;
	int ret;
	QObject *next;
	GString *val;

	key = params;
	val_end = NULL;
	len = strcspn(params, "=,");
	if (len && key[len] != '=') {
	if (starts_with_help_option(key) == len) {
	*help = true;
	s = key + len;
	if (*s == ',') {
	s++;
	}
	return s;
	}
	if (implied_key) {
	/* Desugar implied key */
	key = implied_key;
	val_end = params + len;
	len = strlen(implied_key);
	}
	}
	key_end = key + len;

	/*
	* Loop over key fragments: @s points to current fragment, it
	* applies to @cur. @key_in_cur[] holds the previous fragment.
	*/
	cur = qdict;
	s = key;
	for (;;) {
	/* Want a key index (unless it's first) or a QAPI name */
	if (s != key && key_to_index(s, &end) >= 0) {
	len = end - s;
	} else {
	ret = parse_qapi_name(s, false);
	len = ret < 0 ? 0 : ret;
	}
	assert(s + len <= key_end);
	if (!len \|\| (s + len < key_end && s[len] != '.')) {
	assert(key != implied_key);
	error_setg(errp, "Invalid parameter '%.*s'",
	(int)(key_end - key), key);
	return NULL;
	}
	if (len >= sizeof(key_in_cur)) {
	assert(key != implied_key);
	error_setg(errp, "Parameter%s '%.*s' is too long",
	s != key \|\| s + len != key_end ? " fragment" : "",
	(int)len, s);
	return NULL;
	}

	if (s != key) {
	next = keyval_parse_put(cur, key_in_cur, NULL,
	key, s - 1, errp);
	if (!next) {
	return NULL;
	}
	cur = qobject_to(QDict, next);
	assert(cur);
	}

	memcpy(key_in_cur, s, len);
	key_in_cur[len] = 0;
	s += len;

	if (*s != '.') {
	break;
	}
	s++;
	}

	if (key == implied_key) {
	assert(!*s);
	val = g_string_new_len(params, val_end - params);
	s = val_end;
	if (*s == ',') {
	s++;
	}
	} else {
	if (*s != '=') {
	error_setg(errp, "Expected '=' after parameter '%.*s'",
	(int)(s - key), key);
	return NULL;
	}
	s++;

	val = g_string_new(NULL);
	for (;;) {
	if (!*s) {
	break;
	} else if (*s == ',') {
	s++;
	if (*s != ',') {
	break;
	}
	}
	g_string_append_c(val, *s++);
	}
	}

	if (!keyval_parse_put(cur, key_in_cur, qstring_from_gstring(val),
	key, key_end, errp)) {
	return NULL;
	}
	return s;
	}

	static char reassemble_key(GSList key)
	{
	GString *s = g_string_new("");
	GSList *p;

	for (p = key; p; p = p->next) {
	g_string_prepend_c(s, '.');
	g_string_prepend(s, (char *)p->data);
	}

	return g_string_free(s, FALSE);
	}

	/*
	* Recursive worker for keyval_merge.
	*
	* @str is the path that led to the * current dictionary (to be used for
	* error messages). It is modified internally but restored before the
	* function returns.
	*/
	static void keyval_do_merge(QDict dest, const QDict merged, GString str, Error *errp)
	{
	size_t save_len = str->len;
	const QDictEntry *ent;
	QObject *old_value;

	for (ent = qdict_first(merged); ent; ent = qdict_next(merged, ent)) {
	old_value = qdict_get(dest, ent->key);
	if (old_value) {
	if (qobject_type(old_value) != qobject_type(ent->value)) {
	error_setg(errp, "Parameter '%s%s' used inconsistently",
	str->str, ent->key);
	return;
	} else if (qobject_type(ent->value) == QTYPE_QDICT) {
	/* Merge sub-dictionaries. */
	g_string_append(str, ent->key);
	g_string_append_c(str, '.');
	keyval_do_merge(qobject_to(QDict, old_value),
	qobject_to(QDict, ent->value),
	str, errp);
	g_string_truncate(str, save_len);
	continue;
	} else if (qobject_type(ent->value) == QTYPE_QLIST) {
	/* Append to old list. */
	QList *old = qobject_to(QList, old_value);
	QList *new = qobject_to(QList, ent->value);
	const QListEntry *item;
	QLIST_FOREACH_ENTRY(new, item) {
	qobject_ref(item->value);
	qlist_append_obj(old, item->value);
	}
	continue;
	} else {
	assert(qobject_type(ent->value) == QTYPE_QSTRING);
	}
	}

	qobject_ref(ent->value);
	qdict_put_obj(dest, ent->key, ent->value);
	}
	}

	/* Merge the @merged dictionary into @dest.
	*
	* The dictionaries are expected to be returned by the keyval parser, and
	* therefore the only expected scalar type is the string. In case the same
	* path is present in both @dest and @merged, the semantics are as follows:
	*
	* - lists are concatenated
	*
	* - dictionaries are merged recursively
	*
	* - for scalar values, @merged wins
	*
	* In case an error is reported, @dest may already have been modified.
	*
	* This function can be used to implement semantics analogous to QemuOpts's
	* .merge_lists = true case, or to implement -set for options backed by QDicts.
	*
	* Note: while QemuOpts is commonly used so that repeated keys overwrite
	* ("last one wins"), it can also be used so that repeated keys build up
	* a list. keyval_merge() can only be used when the options' semantics are
	* the former, not the latter.
	*/
	void keyval_merge(QDict dest, const QDict merged, Error **errp)
	{
	GString *str;

	str = g_string_new("");
	keyval_do_merge(dest, merged, str, errp);
	g_string_free(str, TRUE);
	}

	/*
	* Listify @cur recursively.
	* Replace QDicts whose keys are all valid list indexes by QLists.
	* @key_of_cur is the list of key fragments leading up to @cur.
	* On success, return either @cur or its replacement.
	* On failure, store an error through @errp and return NULL.
	*/
	static QObject keyval_listify(QDict cur, GSList key_of_cur, Error *errp)
	{
	GSList key_node;
	bool has_index, has_member;
	const QDictEntry *ent;
	QDict *qdict;
	QObject *val;
	char *key;
	size_t nelt;
	QObject **elt;
	int index, max_index, i;
	QList *list;

	key_node.next = key_of_cur;

	/*
	* Recursively listify @cur's members, and figure out whether @cur
	* itself is to be listified.
	*/
	has_index = false;
	has_member = false;
	for (ent = qdict_first(cur); ent; ent = qdict_next(cur, ent)) {
	if (key_to_index(ent->key, NULL) >= 0) {
	has_index = true;
	} else {
	has_member = true;
	}

	qdict = qobject_to(QDict, ent->value);
	if (!qdict) {
	continue;
	}

	key_node.data = ent->key;
	val = keyval_listify(qdict, &key_node, errp);
	if (!val) {
	return NULL;
	}
	if (val != ent->value) {
	qdict_put_obj(cur, ent->key, val);
	}
	}

	if (has_index && has_member) {
	key = reassemble_key(key_of_cur);
	error_setg(errp, "Parameters '%s*' used inconsistently", key);
	g_free(key);
	return NULL;
	}
	if (!has_index) {
	return QOBJECT(cur);
	}

	/* Copy @cur's values to @elt[] */
	nelt = qdict_size(cur) + 1; /* one extra, for use as sentinel */
	elt = g_new0(QObject *, nelt);
	max_index = -1;
	for (ent = qdict_first(cur); ent; ent = qdict_next(cur, ent)) {
	index = key_to_index(ent->key, NULL);
	assert(index >= 0);
	if (index > max_index) {
	max_index = index;
	}
	/*
	* We iterate @nelt times. If we get one exceeding @nelt
	* here, we will put less than @nelt values into @elt[],
	* triggering the error in the next loop.
	*/
	if ((size_t)index >= nelt - 1) {
	continue;
	}
	/* Even though dict keys are distinct, indexes need not be */
	elt[index] = ent->value;
	}

	/*
	* Make a list from @elt[], reporting the first missing element,
	* if any.
	* If we dropped an index >= nelt in the previous loop, this loop
	* will run into the sentinel and report index @nelt missing.
	*/
	list = qlist_new();
	assert(!elt[nelt-1]); /* need the sentinel to be null */
	for (i = 0; i < MIN(nelt, max_index + 1); i++) {
	if (!elt[i]) {
	key = reassemble_key(key_of_cur);
	error_setg(errp, "Parameter '%s%d' missing", key, i);
	g_free(key);
	g_free(elt);
	qobject_unref(list);
	return NULL;
	}
	qobject_ref(elt[i]);
	qlist_append_obj(list, elt[i]);
	}

	g_free(elt);
	return QOBJECT(list);
	}

	/*
	* Parse @params in QEMU's traditional KEY=VALUE,... syntax.
	*
	* If @implied_key, the first KEY= can be omitted. @implied_key is
	* implied then, and VALUE can't be empty or contain ',' or '='.
	*
	* A parameter "help" or "?" without a value isn't added to the
	* resulting dictionary, but instead is interpreted as help request.
	* All other options are parsed and returned normally so that context
	* specific help can be printed.
	*
	* If @p_help is not NULL, store whether help is requested there.
	* If @p_help is NULL and help is requested, fail.
	*
	* On success, return @dict, now filled with the parsed keys and values.
	*
	* On failure, store an error through @errp and return NULL. Any keys
	* and values parsed so far will be in @dict nevertheless.
	*/
	QDict keyval_parse_into(QDict qdict, const char params, const char implied_key,
	bool p_help, Error *errp)
	{
	QObject *listified;
	const char *s;
	bool help = false;

	s = params;
	while (*s) {
	s = keyval_parse_one(qdict, s, implied_key, &help, errp);
	if (!s) {
	return NULL;
	}
	implied_key = NULL;
	}

	if (p_help) {
	*p_help = help;
	} else if (help) {
	error_setg(errp, "Help is not available for this option");
	return NULL;
	}

	listified = keyval_listify(qdict, NULL, errp);
	if (!listified) {
	return NULL;
	}
	assert(listified == QOBJECT(qdict));
	return qdict;
	}

	/*
	* Parse @params in QEMU's traditional KEY=VALUE,... syntax.
	*
	* If @implied_key, the first KEY= can be omitted. @implied_key is
	* implied then, and VALUE can't be empty or contain ',' or '='.
	*
	* A parameter "help" or "?" without a value isn't added to the
	* resulting dictionary, but instead is interpreted as help request.
	* All other options are parsed and returned normally so that context
	* specific help can be printed.
	*
	* If @p_help is not NULL, store whether help is requested there.
	* If @p_help is NULL and help is requested, fail.
	*
	* On success, return a dictionary of the parsed keys and values.
	* On failure, store an error through @errp and return NULL.
	*/
	QDict keyval_parse(const char params, const char *implied_key,
	bool p_help, Error *errp)
	{
	QDict *qdict = qdict_new();
	QDict *ret = keyval_parse_into(qdict, params, implied_key, p_help, errp);

	if (!ret) {
	qobject_unref(qdict);
	}
	return ret;
	}