/* -*- Mode: C; tab-width: 4; indent-tabs-mode: t; c-basic-offset: 4 -*- */ /* * This library is free software; you can redistribute it and/or * modify it under the terms of the GNU Lesser General Public * License as published by the Free Software Foundation; either * version 2 of the License, or (at your option) any later version. * * This library 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 * Lesser General Public License for more details. * * You should have received a copy of the GNU Lesser General Public * License along with this library; if not, write to the * Free Software Foundation, Inc., 51 Franklin Street, Fifth Floor, * Boston, MA 02110-1301 USA. * * Copyright 2005 - 2014 Red Hat, Inc. */ #include "nm-default.h" #include "nm-utils.h" #include #include #include #include #include #include #include #include #include #if WITH_JANSSON #include #endif #include "nm-common-macros.h" #include "nm-utils-private.h" #include "nm-setting-private.h" #include "crypto.h" #include "nm-setting-bond.h" #include "nm-setting-bridge.h" #include "nm-setting-infiniband.h" #include "nm-setting-ip6-config.h" #include "nm-setting-team.h" #include "nm-setting-vlan.h" #include "nm-setting-wired.h" #include "nm-setting-wireless.h" /** * SECTION:nm-utils * @short_description: Utility functions * * A collection of utility functions for working with SSIDs, IP addresses, Wi-Fi * access points and devices, among other things. */ struct EncodingTriplet { const char *encoding1; const char *encoding2; const char *encoding3; }; struct IsoLangToEncodings { const char * lang; struct EncodingTriplet encodings; }; /* 5-letter language codes */ static const struct IsoLangToEncodings isoLangEntries5[] = { /* Simplified Chinese */ { "zh_cn", {"euc-cn", "gb2312", "gb18030"} }, /* PRC */ { "zh_sg", {"euc-cn", "gb2312", "gb18030"} }, /* Singapore */ /* Traditional Chinese */ { "zh_tw", {"big5", "euc-tw", NULL} }, /* Taiwan */ { "zh_hk", {"big5", "euc-tw", "big5-hkcs"} },/* Hong Kong */ { "zh_mo", {"big5", "euc-tw", NULL} }, /* Macau */ /* Table end */ { NULL, {NULL, NULL, NULL} } }; /* 2-letter language codes; we don't care about the other 3 in this table */ static const struct IsoLangToEncodings isoLangEntries2[] = { /* Japanese */ { "ja", {"euc-jp", "shift_jis", "iso-2022-jp"} }, /* Korean */ { "ko", {"euc-kr", "iso-2022-kr", "johab"} }, /* Thai */ { "th", {"iso-8859-11","windows-874", NULL} }, /* Central European */ { "hu", {"iso-8859-2", "windows-1250", NULL} }, /* Hungarian */ { "cs", {"iso-8859-2", "windows-1250", NULL} }, /* Czech */ { "hr", {"iso-8859-2", "windows-1250", NULL} }, /* Croatian */ { "pl", {"iso-8859-2", "windows-1250", NULL} }, /* Polish */ { "ro", {"iso-8859-2", "windows-1250", NULL} }, /* Romanian */ { "sk", {"iso-8859-2", "windows-1250", NULL} }, /* Slovakian */ { "sl", {"iso-8859-2", "windows-1250", NULL} }, /* Slovenian */ { "sh", {"iso-8859-2", "windows-1250", NULL} }, /* Serbo-Croatian */ /* Cyrillic */ { "ru", {"koi8-r", "windows-1251", "iso-8859-5"} }, /* Russian */ { "be", {"koi8-r", "windows-1251", "iso-8859-5"} }, /* Belorussian */ { "bg", {"windows-1251","koi8-r", "iso-8859-5"} }, /* Bulgarian */ { "mk", {"koi8-r", "windows-1251", "iso-8859-5"} }, /* Macedonian */ { "sr", {"koi8-r", "windows-1251", "iso-8859-5"} }, /* Serbian */ { "uk", {"koi8-u", "koi8-r", "windows-1251"} }, /* Ukranian */ /* Arabic */ { "ar", {"iso-8859-6", "windows-1256", NULL} }, /* Baltic */ { "et", {"iso-8859-4", "windows-1257", NULL} }, /* Estonian */ { "lt", {"iso-8859-4", "windows-1257", NULL} }, /* Lithuanian */ { "lv", {"iso-8859-4", "windows-1257", NULL} }, /* Latvian */ /* Greek */ { "el", {"iso-8859-7", "windows-1253", NULL} }, /* Hebrew */ { "he", {"iso-8859-8", "windows-1255", NULL} }, { "iw", {"iso-8859-8", "windows-1255", NULL} }, /* Turkish */ { "tr", {"iso-8859-9", "windows-1254", NULL} }, /* Table end */ { NULL, {NULL, NULL, NULL} } }; static GHashTable * langToEncodings5 = NULL; static GHashTable * langToEncodings2 = NULL; static void init_lang_to_encodings_hash (void) { struct IsoLangToEncodings *enc; if (G_UNLIKELY (langToEncodings5 == NULL)) { /* Five-letter codes */ enc = (struct IsoLangToEncodings *) &isoLangEntries5[0]; langToEncodings5 = g_hash_table_new (g_str_hash, g_str_equal); while (enc->lang) { g_hash_table_insert (langToEncodings5, (gpointer) enc->lang, (gpointer) &enc->encodings); enc++; } } if (G_UNLIKELY (langToEncodings2 == NULL)) { /* Two-letter codes */ enc = (struct IsoLangToEncodings *) &isoLangEntries2[0]; langToEncodings2 = g_hash_table_new (g_str_hash, g_str_equal); while (enc->lang) { g_hash_table_insert (langToEncodings2, (gpointer) enc->lang, (gpointer) &enc->encodings); enc++; } } } static gboolean get_encodings_for_lang (const char *lang, char **encoding1, char **encoding2, char **encoding3) { struct EncodingTriplet * encodings; gboolean success = FALSE; char * tmp_lang; g_return_val_if_fail (lang != NULL, FALSE); g_return_val_if_fail (encoding1 != NULL, FALSE); g_return_val_if_fail (encoding2 != NULL, FALSE); g_return_val_if_fail (encoding3 != NULL, FALSE); *encoding1 = "iso-8859-1"; *encoding2 = "windows-1251"; *encoding3 = NULL; init_lang_to_encodings_hash (); tmp_lang = g_strdup (lang); if ((encodings = g_hash_table_lookup (langToEncodings5, tmp_lang))) { *encoding1 = (char *) encodings->encoding1; *encoding2 = (char *) encodings->encoding2; *encoding3 = (char *) encodings->encoding3; success = TRUE; } /* Truncate tmp_lang to length of 2 */ if (strlen (tmp_lang) > 2) tmp_lang[2] = '\0'; if (!success && (encodings = g_hash_table_lookup (langToEncodings2, tmp_lang))) { *encoding1 = (char *) encodings->encoding1; *encoding2 = (char *) encodings->encoding2; *encoding3 = (char *) encodings->encoding3; success = TRUE; } g_free (tmp_lang); return success; } /* init libnm */ static gboolean initialized = FALSE; static void __attribute__((constructor)) _nm_utils_init (void) { GModule *self; gpointer func; if (initialized) return; initialized = TRUE; self = g_module_open (NULL, 0); if (g_module_symbol (self, "nm_util_get_private", &func)) g_error ("libnm-util symbols detected; Mixing libnm with libnm-util/libnm-glib is not supported"); g_module_close (self); bindtextdomain (GETTEXT_PACKAGE, LOCALEDIR); bind_textdomain_codeset (GETTEXT_PACKAGE, "UTF-8"); nm_g_type_init (); _nm_dbus_errors_init (); } gboolean _nm_utils_is_manager_process; /* ssid helpers */ /** * nm_utils_ssid_to_utf8: * @ssid: (array length=len): pointer to a buffer containing the SSID data * @len: length of the SSID data in @ssid * * Wi-Fi SSIDs are byte arrays, they are _not_ strings. Thus, an SSID may * contain embedded NULLs and other unprintable characters. Often it is * useful to print the SSID out for debugging purposes, but that should be the * _only_ use of this function. Do not use this function for any persistent * storage of the SSID, since the printable SSID returned from this function * cannot be converted back into the real SSID of the access point. * * This function does almost everything humanly possible to convert the input * into a printable UTF-8 string, using roughly the following procedure: * * 1) if the input data is already UTF-8 safe, no conversion is performed * 2) attempts to get the current system language from the LANG environment * variable, and depending on the language, uses a table of alternative * encodings to try. For example, if LANG=hu_HU, the table may first try * the ISO-8859-2 encoding, and if that fails, try the Windows-1250 encoding. * If all fallback encodings fail, replaces non-UTF-8 characters with '?'. * 3) If the system language was unable to be determined, falls back to the * ISO-8859-1 encoding, then to the Windows-1251 encoding. * 4) If step 3 fails, replaces non-UTF-8 characters with '?'. * * Again, this function should be used for debugging and display purposes * _only_. * * Returns: (transfer full): an allocated string containing a UTF-8 * representation of the SSID, which must be freed by the caller using g_free(). * Returns %NULL on errors. **/ char * nm_utils_ssid_to_utf8 (const guint8 *ssid, gsize len) { char *converted = NULL; char *lang, *e1 = NULL, *e2 = NULL, *e3 = NULL; g_return_val_if_fail (ssid != NULL, NULL); if (g_utf8_validate ((const gchar *) ssid, len, NULL)) return g_strndup ((const gchar *) ssid, len); /* LANG may be a good encoding hint */ g_get_charset ((const char **)(&e1)); if ((lang = getenv ("LANG"))) { char * dot; lang = g_ascii_strdown (lang, -1); if ((dot = strchr (lang, '.'))) *dot = '\0'; get_encodings_for_lang (lang, &e1, &e2, &e3); g_free (lang); } converted = g_convert ((const gchar *) ssid, len, "UTF-8", e1, NULL, NULL, NULL); if (!converted && e2) converted = g_convert ((const gchar *) ssid, len, "UTF-8", e2, NULL, NULL, NULL); if (!converted && e3) converted = g_convert ((const gchar *) ssid, len, "UTF-8", e3, NULL, NULL, NULL); if (!converted) { converted = g_convert_with_fallback ((const gchar *) ssid, len, "UTF-8", e1, "?", NULL, NULL, NULL); } if (!converted) { /* If there is still no converted string, the SSID probably * contains characters not valid in the current locale. Convert * the string to ASCII instead. */ /* Use the printable range of 0x20-0x7E */ gchar *valid_chars = " !\"#$%&'()*+,-./0123456789:;<=>?@" "ABCDEFGHIJKLMNOPQRSTUVWXYZ[\\]^_`" "abcdefghijklmnopqrstuvwxyz{|}~"; converted = g_strndup ((const gchar *)ssid, len); g_strcanon (converted, valid_chars, '?'); } return converted; } /* Shamelessly ripped from the Linux kernel ieee80211 stack */ /** * nm_utils_is_empty_ssid: * @ssid: (array length=len): pointer to a buffer containing the SSID data * @len: length of the SSID data in @ssid * * Different manufacturers use different mechanisms for not broadcasting the * AP's SSID. This function attempts to detect blank/empty SSIDs using a * number of known SSID-cloaking methods. * * Returns: %TRUE if the SSID is "empty", %FALSE if it is not **/ gboolean nm_utils_is_empty_ssid (const guint8 *ssid, gsize len) { /* Single white space is for Linksys APs */ if (len == 1 && ssid[0] == ' ') return TRUE; /* Otherwise, if the entire ssid is 0, we assume it is hidden */ while (len--) { if (ssid[len] != '\0') return FALSE; } return TRUE; } #define ESSID_MAX_SIZE 32 /** * nm_utils_escape_ssid: * @ssid: (array length=len): pointer to a buffer containing the SSID data * @len: length of the SSID data in @ssid * * This function does a quick printable character conversion of the SSID, simply * replacing embedded NULLs and non-printable characters with the hexadecimal * representation of that character. Intended for debugging only, should not * be used for display of SSIDs. * * Returns: pointer to the escaped SSID, which uses an internal static buffer * and will be overwritten by subsequent calls to this function **/ const char * nm_utils_escape_ssid (const guint8 *ssid, gsize len) { static char escaped[ESSID_MAX_SIZE * 2 + 1]; const guint8 *s = ssid; char *d = escaped; if (nm_utils_is_empty_ssid (ssid, len)) { memcpy (escaped, "", sizeof ("")); return escaped; } len = MIN (len, (guint32) ESSID_MAX_SIZE); while (len--) { if (*s == '\0') { *d++ = '\\'; *d++ = '0'; s++; } else { *d++ = *s++; } } *d = '\0'; return escaped; } /** * nm_utils_same_ssid: * @ssid1: (array length=len1): the first SSID to compare * @len1: length of the SSID data in @ssid1 * @ssid2: (array length=len2): the second SSID to compare * @len2: length of the SSID data in @ssid2 * @ignore_trailing_null: %TRUE to ignore one trailing NULL byte * * Earlier versions of the Linux kernel added a NULL byte to the end of the * SSID to enable easy printing of the SSID on the console or in a terminal, * but this behavior was problematic (SSIDs are simply byte arrays, not strings) * and thus was changed. This function compensates for that behavior at the * cost of some compatibility with odd SSIDs that may legitimately have trailing * NULLs, even though that is functionally pointless. * * Returns: %TRUE if the SSIDs are the same, %FALSE if they are not **/ gboolean nm_utils_same_ssid (const guint8 *ssid1, gsize len1, const guint8 *ssid2, gsize len2, gboolean ignore_trailing_null) { g_return_val_if_fail (ssid1 != NULL || len1 == 0, FALSE); g_return_val_if_fail (ssid2 != NULL || len2 == 0, FALSE); if (ssid1 == ssid2 && len1 == len2) return TRUE; if (!ssid1 || !ssid2) return FALSE; if (ignore_trailing_null) { if (len1 && ssid1[len1 - 1] == '\0') len1--; if (len2 && ssid2[len2 - 1] == '\0') len2--; } if (len1 != len2) return FALSE; return memcmp (ssid1, ssid2, len1) == 0 ? TRUE : FALSE; } /** * _nm_utils_strv_find_first: * @list: the strv list to search * @len: the length of the list, or a negative value if @list is %NULL terminated. * @needle: the value to search for. The search is done using strcmp(). * * Searches @list for @needle and returns the index of the first match (based * on strcmp()). * * For convenience, @list has type 'char**' instead of 'const char **'. * * Returns: index of first occurrence or -1 if @needle is not found in @list. */ gssize _nm_utils_strv_find_first (char **list, gssize len, const char *needle) { gssize i; if (len > 0) { g_return_val_if_fail (list, -1); if (!needle) { /* if we search a list with known length, %NULL is a valid @needle. */ for (i = 0; i < len; i++) { if (!list[i]) return i; } } else { for (i = 0; i < len; i++) { if (list[i] && !strcmp (needle, list[i])) return i; } } } else if (len < 0) { g_return_val_if_fail (needle, -1); if (list) { for (i = 0; list[i]; i++) { if (strcmp (needle, list[i]) == 0) return i; } } } return -1; } char ** _nm_utils_strv_cleanup (char **strv, gboolean strip_whitespace, gboolean skip_empty, gboolean skip_repeated) { guint i, j; if (!strv || !*strv) return strv; if (strip_whitespace) { for (i = 0; strv[i]; i++) g_strstrip (strv[i]); } if (!skip_empty && !skip_repeated) return strv; j = 0; for (i = 0; strv[i]; i++) { if ( (skip_empty && !*strv[i]) || (skip_repeated && _nm_utils_strv_find_first (strv, j, strv[i]) >= 0)) g_free (strv[i]); else strv[j++] = strv[i]; } strv[j] = NULL; return strv; } gboolean _nm_utils_string_slist_validate (GSList *list, const char **valid_values) { GSList *iter; for (iter = list; iter; iter = iter->next) { if (!g_strv_contains (valid_values, (char *) iter->data)) return FALSE; } return TRUE; } /** * _nm_utils_hash_values_to_slist: * @hash: a #GHashTable * * Utility function to iterate over a hash table and return * it's values as a #GSList. * * Returns: (element-type gpointer) (transfer container): a newly allocated #GSList * containing the values of the hash table. The caller must free the * returned list with g_slist_free(). The hash values are not owned * by the returned list. **/ GSList * _nm_utils_hash_values_to_slist (GHashTable *hash) { GSList *list = NULL; GHashTableIter iter; void *value; g_return_val_if_fail (hash, NULL); g_hash_table_iter_init (&iter, hash); while (g_hash_table_iter_next (&iter, NULL, &value)) list = g_slist_prepend (list, value); return list; } GVariant * _nm_utils_strdict_to_dbus (const GValue *prop_value) { GHashTable *hash; GHashTableIter iter; gpointer key, value; GVariantBuilder builder; g_variant_builder_init (&builder, G_VARIANT_TYPE ("a{ss}")); hash = g_value_get_boxed (prop_value); if (hash) { g_hash_table_iter_init (&iter, hash); while (g_hash_table_iter_next (&iter, &key, &value)) g_variant_builder_add (&builder, "{ss}", key, value); } return g_variant_builder_end (&builder); } void _nm_utils_strdict_from_dbus (GVariant *dbus_value, GValue *prop_value) { GVariantIter iter; const char *key, *value; GHashTable *hash; hash = g_hash_table_new_full (g_str_hash, g_str_equal, g_free, g_free); g_variant_iter_init (&iter, dbus_value); while (g_variant_iter_next (&iter, "{&s&s}", &key, &value)) g_hash_table_insert (hash, g_strdup (key), g_strdup (value)); g_value_take_boxed (prop_value, hash); } GHashTable * _nm_utils_copy_strdict (GHashTable *strdict) { GHashTable *copy; GHashTableIter iter; gpointer key, value; copy = g_hash_table_new_full (g_str_hash, g_str_equal, g_free, g_free); if (strdict) { g_hash_table_iter_init (&iter, strdict); while (g_hash_table_iter_next (&iter, &key, &value)) g_hash_table_insert (copy, g_strdup (key), g_strdup (value)); } return copy; } GPtrArray * _nm_utils_copy_slist_to_array (const GSList *list, NMUtilsCopyFunc copy_func, GDestroyNotify unref_func) { const GSList *iter; GPtrArray *array; array = g_ptr_array_new_with_free_func (unref_func); for (iter = list; iter; iter = iter->next) g_ptr_array_add (array, copy_func ? copy_func (iter->data) : iter->data); return array; } GSList * _nm_utils_copy_array_to_slist (const GPtrArray *array, NMUtilsCopyFunc copy_func) { GSList *slist = NULL; gpointer item; int i; if (!array) return NULL; for (i = 0; i < array->len; i++) { item = array->pdata[i]; slist = g_slist_prepend (slist, copy_func (item)); } return g_slist_reverse (slist); } GPtrArray * _nm_utils_copy_array (const GPtrArray *array, NMUtilsCopyFunc copy_func, GDestroyNotify free_func) { GPtrArray *copy; int i; if (!array) return g_ptr_array_new_with_free_func (free_func); copy = g_ptr_array_new_full (array->len, free_func); for (i = 0; i < array->len; i++) g_ptr_array_add (copy, copy_func (array->pdata[i])); return copy; } GPtrArray * _nm_utils_copy_object_array (const GPtrArray *array) { return _nm_utils_copy_array (array, g_object_ref, g_object_unref); } gssize _nm_utils_ptrarray_find_first (gconstpointer *list, gssize len, gconstpointer needle) { gssize i; if (len == 0) return -1; if (len > 0) { g_return_val_if_fail (list, -1); for (i = 0; i < len; i++) { if (list[i] == needle) return i; } } else { g_return_val_if_fail (needle, -1); for (i = 0; list && list[i]; i++) { if (list[i] == needle) return i; } } return -1; } gssize _nm_utils_ptrarray_find_binary_search (gconstpointer *list, gsize len, gconstpointer needle, GCompareDataFunc cmpfcn, gpointer user_data) { gssize imin, imax, imid; int cmp; g_return_val_if_fail (list || !len, ~((gssize) 0)); g_return_val_if_fail (cmpfcn, ~((gssize) 0)); imin = 0; if (len == 0) return ~imin; imax = len - 1; while (imin <= imax) { imid = imin + (imax - imin) / 2; cmp = cmpfcn (list[imid], needle, user_data); if (cmp == 0) return imid; if (cmp < 0) imin = imid + 1; else imax = imid - 1; } /* return the inverse of @imin. This is a negative number, but * also is ~imin the position where the value should be inserted. */ return ~imin; } gssize _nm_utils_array_find_binary_search (gconstpointer list, gsize elem_size, gsize len, gconstpointer needle, GCompareDataFunc cmpfcn, gpointer user_data) { gssize imin, imax, imid; int cmp; g_return_val_if_fail (list || !len, ~((gssize) 0)); g_return_val_if_fail (cmpfcn, ~((gssize) 0)); g_return_val_if_fail (elem_size > 0, ~((gssize) 0)); imin = 0; if (len == 0) return ~imin; imax = len - 1; while (imin <= imax) { imid = imin + (imax - imin) / 2; cmp = cmpfcn (&((const char *) list)[elem_size * imid], needle, user_data); if (cmp == 0) return imid; if (cmp < 0) imin = imid + 1; else imax = imid - 1; } /* return the inverse of @imin. This is a negative number, but * also is ~imin the position where the value should be inserted. */ return ~imin; } GVariant * _nm_utils_bytes_to_dbus (const GValue *prop_value) { GBytes *bytes = g_value_get_boxed (prop_value); if (bytes) { return g_variant_new_fixed_array (G_VARIANT_TYPE_BYTE, g_bytes_get_data (bytes, NULL), g_bytes_get_size (bytes), 1); } else { return g_variant_new_fixed_array (G_VARIANT_TYPE_BYTE, NULL, 0, 1); } } void _nm_utils_bytes_from_dbus (GVariant *dbus_value, GValue *prop_value) { GBytes *bytes; if (g_variant_n_children (dbus_value)) { gconstpointer data; gsize length; data = g_variant_get_fixed_array (dbus_value, &length, 1); bytes = g_bytes_new (data, length); } else bytes = NULL; g_value_take_boxed (prop_value, bytes); } GSList * _nm_utils_strv_to_slist (char **strv, gboolean deep_copy) { int i; GSList *list = NULL; if (strv) { if (deep_copy) { for (i = 0; strv[i]; i++) list = g_slist_prepend (list, g_strdup (strv[i])); } else { for (i = 0; strv[i]; i++) list = g_slist_prepend (list, strv[i]); } } return g_slist_reverse (list); } char ** _nm_utils_slist_to_strv (GSList *slist, gboolean deep_copy) { GSList *iter; char **strv; int len, i; len = g_slist_length (slist); strv = g_new (char *, len + 1); if (deep_copy) { for (i = 0, iter = slist; iter; iter = iter->next, i++) strv[i] = g_strdup (iter->data); } else { for (i = 0, iter = slist; iter; iter = iter->next, i++) strv[i] = iter->data; } strv[i] = NULL; return strv; } GPtrArray * _nm_utils_strv_to_ptrarray (char **strv) { GPtrArray *ptrarray; int i; ptrarray = g_ptr_array_new_with_free_func (g_free); if (strv) { for (i = 0; strv[i]; i++) g_ptr_array_add (ptrarray, g_strdup (strv[i])); } return ptrarray; } char ** _nm_utils_ptrarray_to_strv (GPtrArray *ptrarray) { char **strv; int i; if (!ptrarray) return g_new0 (char *, 1); strv = g_new (char *, ptrarray->len + 1); for (i = 0; i < ptrarray->len; i++) strv[i] = g_strdup (ptrarray->pdata[i]); strv[i] = NULL; return strv; } /** * _nm_utils_strv_equal: * @strv1: a string array * @strv2: a string array * * Compare NULL-terminated string arrays for equality. * * Returns: %TRUE if the arrays are equal, %FALSE otherwise. **/ gboolean _nm_utils_strv_equal (char **strv1, char **strv2) { if (strv1 == strv2) return TRUE; if (!strv1 || !strv2) return FALSE; for ( ; *strv1 && *strv2 && !strcmp (*strv1, *strv2); strv1++, strv2++) ; return !*strv1 && !*strv2; } /** * _nm_utils_strsplit_set: * @str: string to split * @delimiters: string of delimiter characters * @max_tokens: the maximum number of tokens to split string into. When it is * less than 1, the @str is split completely. * * Utility function for splitting string into a string array. It is a wrapper * for g_strsplit_set(), but it also removes empty strings from the vector as * they are not useful in most cases. * * Returns: (transfer full): a newly allocated NULL-terminated array of strings. * The caller must free the returned array with g_strfreev(). **/ char ** _nm_utils_strsplit_set (const char *str, const char *delimiters, int max_tokens) { char **result; uint i; uint j; result = g_strsplit_set (str, delimiters, max_tokens); /* remove empty strings */ for (i = 0; result && result[i]; i++) { if (*result[i] == '\0') { g_free (result[i]); for (j = i; result[j]; j++) result[j] = result[j + 1]; i--; } } return result; } static gboolean device_supports_ap_ciphers (guint32 dev_caps, guint32 ap_flags, gboolean static_wep) { gboolean have_pair = FALSE; gboolean have_group = FALSE; /* Device needs to support at least one pairwise and one group cipher */ /* Pairwise */ if (static_wep) { /* Static WEP only uses group ciphers */ have_pair = TRUE; } else { if (dev_caps & NM_WIFI_DEVICE_CAP_CIPHER_WEP40) if (ap_flags & NM_802_11_AP_SEC_PAIR_WEP40) have_pair = TRUE; if (dev_caps & NM_WIFI_DEVICE_CAP_CIPHER_WEP104) if (ap_flags & NM_802_11_AP_SEC_PAIR_WEP104) have_pair = TRUE; if (dev_caps & NM_WIFI_DEVICE_CAP_CIPHER_TKIP) if (ap_flags & NM_802_11_AP_SEC_PAIR_TKIP) have_pair = TRUE; if (dev_caps & NM_WIFI_DEVICE_CAP_CIPHER_CCMP) if (ap_flags & NM_802_11_AP_SEC_PAIR_CCMP) have_pair = TRUE; } /* Group */ if (dev_caps & NM_WIFI_DEVICE_CAP_CIPHER_WEP40) if (ap_flags & NM_802_11_AP_SEC_GROUP_WEP40) have_group = TRUE; if (dev_caps & NM_WIFI_DEVICE_CAP_CIPHER_WEP104) if (ap_flags & NM_802_11_AP_SEC_GROUP_WEP104) have_group = TRUE; if (!static_wep) { if (dev_caps & NM_WIFI_DEVICE_CAP_CIPHER_TKIP) if (ap_flags & NM_802_11_AP_SEC_GROUP_TKIP) have_group = TRUE; if (dev_caps & NM_WIFI_DEVICE_CAP_CIPHER_CCMP) if (ap_flags & NM_802_11_AP_SEC_GROUP_CCMP) have_group = TRUE; } return (have_pair && have_group); } /** * nm_utils_ap_mode_security_valid: * @type: the security type to check device capabilties against, * e.g. #NMU_SEC_STATIC_WEP * @wifi_caps: bitfield of the capabilities of the specific Wi-Fi device, e.g. * #NM_WIFI_DEVICE_CAP_CIPHER_WEP40 * * Given a set of device capabilities, and a desired security type to check * against, determines whether the combination of device capabilities and * desired security type are valid for AP/Hotspot connections. * * Returns: %TRUE if the device capabilities are compatible with the desired * @type, %FALSE if they are not. **/ gboolean nm_utils_ap_mode_security_valid (NMUtilsSecurityType type, NMDeviceWifiCapabilities wifi_caps) { if (!(wifi_caps & NM_WIFI_DEVICE_CAP_AP)) return FALSE; /* Return TRUE for any security that wpa_supplicant's lightweight AP * mode can handle: which is open, WEP, and WPA/WPA2 PSK. */ switch (type) { case NMU_SEC_NONE: case NMU_SEC_STATIC_WEP: case NMU_SEC_WPA_PSK: case NMU_SEC_WPA2_PSK: return TRUE; default: break; } return FALSE; } /** * nm_utils_security_valid: * @type: the security type to check AP flags and device capabilties against, * e.g. #NMU_SEC_STATIC_WEP * @wifi_caps: bitfield of the capabilities of the specific Wi-Fi device, e.g. * #NM_WIFI_DEVICE_CAP_CIPHER_WEP40 * @have_ap: whether the @ap_flags, @ap_wpa, and @ap_rsn arguments are valid * @adhoc: whether the capabilities being tested are from an Ad-Hoc AP (IBSS) * @ap_flags: bitfield of AP capabilities, e.g. #NM_802_11_AP_FLAGS_PRIVACY * @ap_wpa: bitfield of AP capabilties derived from the AP's WPA beacon, * e.g. (#NM_802_11_AP_SEC_PAIR_TKIP | #NM_802_11_AP_SEC_KEY_MGMT_PSK) * @ap_rsn: bitfield of AP capabilties derived from the AP's RSN/WPA2 beacon, * e.g. (#NM_802_11_AP_SEC_PAIR_CCMP | #NM_802_11_AP_SEC_PAIR_TKIP) * * Given a set of device capabilities, and a desired security type to check * against, determines whether the combination of device, desired security * type, and AP capabilities intersect. * * NOTE: this function cannot handle checking security for AP/Hotspot mode; * use nm_utils_ap_mode_security_valid() instead. * * Returns: %TRUE if the device capabilities and AP capabilties intersect and are * compatible with the desired @type, %FALSE if they are not **/ gboolean nm_utils_security_valid (NMUtilsSecurityType type, NMDeviceWifiCapabilities wifi_caps, gboolean have_ap, gboolean adhoc, NM80211ApFlags ap_flags, NM80211ApSecurityFlags ap_wpa, NM80211ApSecurityFlags ap_rsn) { gboolean good = TRUE; if (!have_ap) { if (type == NMU_SEC_NONE) return TRUE; if ( (type == NMU_SEC_STATIC_WEP) || ((type == NMU_SEC_DYNAMIC_WEP) && !adhoc) || ((type == NMU_SEC_LEAP) && !adhoc)) { if (wifi_caps & (NM_WIFI_DEVICE_CAP_CIPHER_WEP40 | NM_WIFI_DEVICE_CAP_CIPHER_WEP104)) return TRUE; else return FALSE; } } switch (type) { case NMU_SEC_NONE: g_assert (have_ap); if (ap_flags & NM_802_11_AP_FLAGS_PRIVACY) return FALSE; if (ap_wpa || ap_rsn) return FALSE; break; case NMU_SEC_LEAP: /* require PRIVACY bit for LEAP? */ if (adhoc) return FALSE; /* Fall through */ case NMU_SEC_STATIC_WEP: g_assert (have_ap); if (!(ap_flags & NM_802_11_AP_FLAGS_PRIVACY)) return FALSE; if (ap_wpa || ap_rsn) { if (!device_supports_ap_ciphers (wifi_caps, ap_wpa, TRUE)) if (!device_supports_ap_ciphers (wifi_caps, ap_rsn, TRUE)) return FALSE; } break; case NMU_SEC_DYNAMIC_WEP: if (adhoc) return FALSE; g_assert (have_ap); if (ap_rsn || !(ap_flags & NM_802_11_AP_FLAGS_PRIVACY)) return FALSE; /* Some APs broadcast minimal WPA-enabled beacons that must be handled */ if (ap_wpa) { if (!(ap_wpa & NM_802_11_AP_SEC_KEY_MGMT_802_1X)) return FALSE; if (!device_supports_ap_ciphers (wifi_caps, ap_wpa, FALSE)) return FALSE; } break; case NMU_SEC_WPA_PSK: if (adhoc) return FALSE; /* FIXME: Kernel WPA Ad-Hoc support is buggy */ if (!(wifi_caps & NM_WIFI_DEVICE_CAP_WPA)) return FALSE; if (have_ap) { /* Ad-Hoc WPA APs won't necessarily have the PSK flag set, and * they don't have any pairwise ciphers. */ if (adhoc) { /* coverity[dead_error_line] */ if ( (ap_wpa & NM_802_11_AP_SEC_GROUP_TKIP) && (wifi_caps & NM_WIFI_DEVICE_CAP_CIPHER_TKIP)) return TRUE; if ( (ap_wpa & NM_802_11_AP_SEC_GROUP_CCMP) && (wifi_caps & NM_WIFI_DEVICE_CAP_CIPHER_CCMP)) return TRUE; } else { if (ap_wpa & NM_802_11_AP_SEC_KEY_MGMT_PSK) { if ( (ap_wpa & NM_802_11_AP_SEC_PAIR_TKIP) && (wifi_caps & NM_WIFI_DEVICE_CAP_CIPHER_TKIP)) return TRUE; if ( (ap_wpa & NM_802_11_AP_SEC_PAIR_CCMP) && (wifi_caps & NM_WIFI_DEVICE_CAP_CIPHER_CCMP)) return TRUE; } } return FALSE; } break; case NMU_SEC_WPA2_PSK: if (adhoc) return FALSE; /* FIXME: Kernel WPA Ad-Hoc support is buggy */ if (!(wifi_caps & NM_WIFI_DEVICE_CAP_RSN)) return FALSE; if (have_ap) { /* Ad-Hoc WPA APs won't necessarily have the PSK flag set, and * they don't have any pairwise ciphers, nor any RSA flags yet. */ if (adhoc) { /* coverity[dead_error_line] */ if (wifi_caps & NM_WIFI_DEVICE_CAP_CIPHER_TKIP) return TRUE; if (wifi_caps & NM_WIFI_DEVICE_CAP_CIPHER_CCMP) return TRUE; } else { if (ap_rsn & NM_802_11_AP_SEC_KEY_MGMT_PSK) { if ( (ap_rsn & NM_802_11_AP_SEC_PAIR_TKIP) && (wifi_caps & NM_WIFI_DEVICE_CAP_CIPHER_TKIP)) return TRUE; if ( (ap_rsn & NM_802_11_AP_SEC_PAIR_CCMP) && (wifi_caps & NM_WIFI_DEVICE_CAP_CIPHER_CCMP)) return TRUE; } } return FALSE; } break; case NMU_SEC_WPA_ENTERPRISE: if (adhoc) return FALSE; if (!(wifi_caps & NM_WIFI_DEVICE_CAP_WPA)) return FALSE; if (have_ap) { if (!(ap_wpa & NM_802_11_AP_SEC_KEY_MGMT_802_1X)) return FALSE; /* Ensure at least one WPA cipher is supported */ if (!device_supports_ap_ciphers (wifi_caps, ap_wpa, FALSE)) return FALSE; } break; case NMU_SEC_WPA2_ENTERPRISE: if (adhoc) return FALSE; if (!(wifi_caps & NM_WIFI_DEVICE_CAP_RSN)) return FALSE; if (have_ap) { if (!(ap_rsn & NM_802_11_AP_SEC_KEY_MGMT_802_1X)) return FALSE; /* Ensure at least one WPA cipher is supported */ if (!device_supports_ap_ciphers (wifi_caps, ap_rsn, FALSE)) return FALSE; } break; default: good = FALSE; break; } return good; } /** * nm_utils_wep_key_valid: * @key: a string that might be a WEP key * @wep_type: the #NMWepKeyType type of the WEP key * * Checks if @key is a valid WEP key * * Returns: %TRUE if @key is a WEP key, %FALSE if not */ gboolean nm_utils_wep_key_valid (const char *key, NMWepKeyType wep_type) { int keylen, i; if (!key) return FALSE; if (wep_type == NM_WEP_KEY_TYPE_UNKNOWN) { return nm_utils_wep_key_valid (key, NM_WEP_KEY_TYPE_KEY) || nm_utils_wep_key_valid (key, NM_WEP_KEY_TYPE_PASSPHRASE); } keylen = strlen (key); if (wep_type == NM_WEP_KEY_TYPE_KEY) { if (keylen == 10 || keylen == 26) { /* Hex key */ for (i = 0; i < keylen; i++) { if (!g_ascii_isxdigit (key[i])) return FALSE; } } else if (keylen == 5 || keylen == 13) { /* ASCII key */ for (i = 0; i < keylen; i++) { if (!g_ascii_isprint (key[i])) return FALSE; } } else return FALSE; } else if (wep_type == NM_WEP_KEY_TYPE_PASSPHRASE) { if (!keylen || keylen > 64) return FALSE; } return TRUE; } /** * nm_utils_wpa_psk_valid: * @psk: a string that might be a WPA PSK * * Checks if @psk is a valid WPA PSK * * Returns: %TRUE if @psk is a WPA PSK, %FALSE if not */ gboolean nm_utils_wpa_psk_valid (const char *psk) { int psklen, i; if (!psk) return FALSE; psklen = strlen (psk); if (psklen < 8 || psklen > 64) return FALSE; if (psklen == 64) { /* Hex PSK */ for (i = 0; i < psklen; i++) { if (!g_ascii_isxdigit (psk[i])) return FALSE; } } return TRUE; } /** * nm_utils_ip4_dns_to_variant: * @dns: (type utf8): an array of IP address strings * * Utility function to convert an array of IP address strings int a #GVariant of * type 'au' representing an array of IPv4 addresses. * * Returns: (transfer none): a new floating #GVariant representing @dns. **/ GVariant * nm_utils_ip4_dns_to_variant (char **dns) { GVariantBuilder builder; int i; g_variant_builder_init (&builder, G_VARIANT_TYPE ("au")); if (dns) { for (i = 0; dns[i]; i++) { guint32 ip = 0; inet_pton (AF_INET, dns[i], &ip); g_variant_builder_add (&builder, "u", ip); } } return g_variant_builder_end (&builder); } /** * nm_utils_ip4_dns_from_variant: * @value: a #GVariant of type 'au' * * Utility function to convert a #GVariant of type 'au' representing a list of * IPv4 addresses into an array of IP address strings. * * Returns: (transfer full) (type utf8): a %NULL-terminated array of IP address strings. **/ char ** nm_utils_ip4_dns_from_variant (GVariant *value) { const guint32 *array; gsize length; char **dns; int i; g_return_val_if_fail (g_variant_is_of_type (value, G_VARIANT_TYPE ("au")), NULL); array = g_variant_get_fixed_array (value, &length, sizeof (guint32)); dns = g_new (char *, length + 1); for (i = 0; i < length; i++) dns[i] = g_strdup (nm_utils_inet4_ntop (array[i], NULL)); dns[i] = NULL; return dns; } /** * nm_utils_ip4_addresses_to_variant: * @addresses: (element-type NMIPAddress): an array of #NMIPAddress objects * @gateway: (allow-none): the gateway IP address * * Utility function to convert a #GPtrArray of #NMIPAddress objects representing * IPv4 addresses into a #GVariant of type 'aau' representing an array of * NetworkManager IPv4 addresses (which are tuples of address, prefix, and * gateway). The "gateway" field of the first address will get the value of * @gateway (if non-%NULL). In all of the other addresses, that field will be 0. * * Returns: (transfer none): a new floating #GVariant representing @addresses. **/ GVariant * nm_utils_ip4_addresses_to_variant (GPtrArray *addresses, const char *gateway) { GVariantBuilder builder; int i; g_variant_builder_init (&builder, G_VARIANT_TYPE ("aau")); if (addresses) { for (i = 0; i < addresses->len; i++) { NMIPAddress *addr = addresses->pdata[i]; guint32 array[3]; if (nm_ip_address_get_family (addr) != AF_INET) continue; nm_ip_address_get_address_binary (addr, &array[0]); array[1] = nm_ip_address_get_prefix (addr); if (i == 0 && gateway) inet_pton (AF_INET, gateway, &array[2]); else array[2] = 0; g_variant_builder_add (&builder, "@au", g_variant_new_fixed_array (G_VARIANT_TYPE_UINT32, array, 3, sizeof (guint32))); } } return g_variant_builder_end (&builder); } /** * nm_utils_ip4_addresses_from_variant: * @value: a #GVariant of type 'aau' * @out_gateway: (out) (allow-none) (transfer full): on return, will contain the IP gateway * * Utility function to convert a #GVariant of type 'aau' representing a list of * NetworkManager IPv4 addresses (which are tuples of address, prefix, and * gateway) into a #GPtrArray of #NMIPAddress objects. The "gateway" field of * the first address (if set) will be returned in @out_gateway; the "gateway" fields * of the other addresses are ignored. * * Returns: (transfer full) (element-type NMIPAddress): a newly allocated * #GPtrArray of #NMIPAddress objects **/ GPtrArray * nm_utils_ip4_addresses_from_variant (GVariant *value, char **out_gateway) { GPtrArray *addresses; GVariantIter iter; GVariant *addr_var; g_return_val_if_fail (g_variant_is_of_type (value, G_VARIANT_TYPE ("aau")), NULL); if (out_gateway) *out_gateway = NULL; g_variant_iter_init (&iter, value); addresses = g_ptr_array_new_with_free_func ((GDestroyNotify) nm_ip_address_unref); while (g_variant_iter_next (&iter, "@au", &addr_var)) { const guint32 *addr_array; gsize length; NMIPAddress *addr; GError *error = NULL; addr_array = g_variant_get_fixed_array (addr_var, &length, sizeof (guint32)); if (length < 3) { g_warning ("Ignoring invalid IP4 address"); g_variant_unref (addr_var); continue; } addr = nm_ip_address_new_binary (AF_INET, &addr_array[0], addr_array[1], &error); if (addr) { g_ptr_array_add (addresses, addr); if (addr_array[2] && out_gateway && !*out_gateway) *out_gateway = g_strdup (nm_utils_inet4_ntop (addr_array[2], NULL)); } else { g_warning ("Ignoring invalid IP4 address: %s", error->message); g_clear_error (&error); } g_variant_unref (addr_var); } return addresses; } /** * nm_utils_ip4_routes_to_variant: * @routes: (element-type NMIPRoute): an array of #NMIP4Route objects * * Utility function to convert a #GPtrArray of #NMIPRoute objects representing * IPv4 routes into a #GVariant of type 'aau' representing an array of * NetworkManager IPv4 routes (which are tuples of route, prefix, next hop, and * metric). * * Returns: (transfer none): a new floating #GVariant representing @routes. **/ GVariant * nm_utils_ip4_routes_to_variant (GPtrArray *routes) { GVariantBuilder builder; int i; g_variant_builder_init (&builder, G_VARIANT_TYPE ("aau")); if (routes) { for (i = 0; i < routes->len; i++) { NMIPRoute *route = routes->pdata[i]; guint32 array[4]; if (nm_ip_route_get_family (route) != AF_INET) continue; nm_ip_route_get_dest_binary (route, &array[0]); array[1] = nm_ip_route_get_prefix (route); nm_ip_route_get_next_hop_binary (route, &array[2]); /* The old routes format uses "0" for default, not "-1" */ array[3] = MAX (0, nm_ip_route_get_metric (route)); g_variant_builder_add (&builder, "@au", g_variant_new_fixed_array (G_VARIANT_TYPE_UINT32, array, 4, sizeof (guint32))); } } return g_variant_builder_end (&builder); } /** * nm_utils_ip4_routes_from_variant: * @value: #GVariant of type 'aau' * * Utility function to convert a #GVariant of type 'aau' representing an array * of NetworkManager IPv4 routes (which are tuples of route, prefix, next hop, * and metric) into a #GPtrArray of #NMIPRoute objects. * * Returns: (transfer full) (element-type NMIPRoute): a newly allocated * #GPtrArray of #NMIPRoute objects **/ GPtrArray * nm_utils_ip4_routes_from_variant (GVariant *value) { GVariantIter iter; GVariant *route_var; GPtrArray *routes; g_return_val_if_fail (g_variant_is_of_type (value, G_VARIANT_TYPE ("aau")), NULL); g_variant_iter_init (&iter, value); routes = g_ptr_array_new_with_free_func ((GDestroyNotify) nm_ip_route_unref); while (g_variant_iter_next (&iter, "@au", &route_var)) { const guint32 *route_array; gsize length; NMIPRoute *route; GError *error = NULL; route_array = g_variant_get_fixed_array (route_var, &length, sizeof (guint32)); if (length < 4) { g_warning ("Ignoring invalid IP4 route"); g_variant_unref (route_var); continue; } route = nm_ip_route_new_binary (AF_INET, &route_array[0], route_array[1], &route_array[2], /* The old routes format uses "0" for default, not "-1" */ route_array[3] ? (gint64) route_array[3] : -1, &error); if (route) g_ptr_array_add (routes, route); else { g_warning ("Ignoring invalid IP4 route: %s", error->message); g_clear_error (&error); } g_variant_unref (route_var); } return routes; } /** * nm_utils_ip4_netmask_to_prefix: * @netmask: an IPv4 netmask in network byte order * * Returns: the CIDR prefix represented by the netmask **/ guint32 nm_utils_ip4_netmask_to_prefix (guint32 netmask) { guint32 prefix; guint8 v; const guint8 *p = (guint8 *) &netmask; if (p[3]) { prefix = 24; v = p[3]; } else if (p[2]) { prefix = 16; v = p[2]; } else if (p[1]) { prefix = 8; v = p[1]; } else { prefix = 0; v = p[0]; } while (v) { prefix++; v <<= 1; } return prefix; } /** * nm_utils_ip4_prefix_to_netmask: * @prefix: a CIDR prefix * * Returns: the netmask represented by the prefix, in network byte order **/ guint32 nm_utils_ip4_prefix_to_netmask (guint32 prefix) { return prefix < 32 ? ~htonl(0xFFFFFFFF >> prefix) : 0xFFFFFFFF; } /** * nm_utils_ip4_get_default_prefix: * @ip: an IPv4 address (in network byte order) * * When the Internet was originally set up, various ranges of IP addresses were * segmented into three network classes: A, B, and C. This function will return * a prefix that is associated with the IP address specified defining where it * falls in the predefined classes. * * Returns: the default class prefix for the given IP **/ /* The function is originally from ipcalc.c of Red Hat's initscripts. */ guint32 nm_utils_ip4_get_default_prefix (guint32 ip) { if (((ntohl (ip) & 0xFF000000) >> 24) <= 127) return 8; /* Class A - 255.0.0.0 */ else if (((ntohl (ip) & 0xFF000000) >> 24) <= 191) return 16; /* Class B - 255.255.0.0 */ return 24; /* Class C - 255.255.255.0 */ } /** * nm_utils_ip6_dns_to_variant: * @dns: (type utf8): an array of IP address strings * * Utility function to convert an array of IP address strings int a #GVariant of * type 'aay' representing an array of IPv6 addresses. * * Returns: (transfer none): a new floating #GVariant representing @dns. **/ GVariant * nm_utils_ip6_dns_to_variant (char **dns) { GVariantBuilder builder; int i; g_variant_builder_init (&builder, G_VARIANT_TYPE ("aay")); if (dns) { for (i = 0; dns[i]; i++) { struct in6_addr ip; inet_pton (AF_INET6, dns[i], &ip); g_variant_builder_add (&builder, "@ay", g_variant_new_fixed_array (G_VARIANT_TYPE_BYTE, &ip, sizeof (ip), 1)); } } return g_variant_builder_end (&builder); } /** * nm_utils_ip6_dns_from_variant: * @value: a #GVariant of type 'aay' * * Utility function to convert a #GVariant of type 'aay' representing a list of * IPv6 addresses into an array of IP address strings. * * Returns: (transfer full) (type utf8): a %NULL-terminated array of IP address strings. **/ char ** nm_utils_ip6_dns_from_variant (GVariant *value) { GVariantIter iter; GVariant *ip_var; char **dns; int i; g_return_val_if_fail (g_variant_is_of_type (value, G_VARIANT_TYPE ("aay")), NULL); dns = g_new (char *, g_variant_n_children (value) + 1); g_variant_iter_init (&iter, value); i = 0; while (g_variant_iter_next (&iter, "@ay", &ip_var)) { gsize length; const struct in6_addr *ip = g_variant_get_fixed_array (ip_var, &length, 1); if (length != sizeof (struct in6_addr)) { g_warning ("%s: ignoring invalid IP6 address of length %d", __func__, (int) length); g_variant_unref (ip_var); continue; } dns[i++] = g_strdup (nm_utils_inet6_ntop (ip, NULL)); g_variant_unref (ip_var); } dns[i] = NULL; return dns; } /** * nm_utils_ip6_addresses_to_variant: * @addresses: (element-type NMIPAddress): an array of #NMIPAddress objects * @gateway: (allow-none): the gateway IP address * * Utility function to convert a #GPtrArray of #NMIPAddress objects representing * IPv6 addresses into a #GVariant of type 'a(ayuay)' representing an array of * NetworkManager IPv6 addresses (which are tuples of address, prefix, and * gateway). The "gateway" field of the first address will get the value of * @gateway (if non-%NULL). In all of the other addresses, that field will be * all 0s. * * Returns: (transfer none): a new floating #GVariant representing @addresses. **/ GVariant * nm_utils_ip6_addresses_to_variant (GPtrArray *addresses, const char *gateway) { GVariantBuilder builder; int i; g_variant_builder_init (&builder, G_VARIANT_TYPE ("a(ayuay)")); if (addresses) { for (i = 0; i < addresses->len; i++) { NMIPAddress *addr = addresses->pdata[i]; struct in6_addr ip_bytes, gateway_bytes; GVariant *ip_var, *gateway_var; guint32 prefix; if (nm_ip_address_get_family (addr) != AF_INET6) continue; nm_ip_address_get_address_binary (addr, &ip_bytes); ip_var = g_variant_new_fixed_array (G_VARIANT_TYPE_BYTE, &ip_bytes, 16, 1); prefix = nm_ip_address_get_prefix (addr); if (i == 0 && gateway) inet_pton (AF_INET6, gateway, &gateway_bytes); else memset (&gateway_bytes, 0, sizeof (gateway_bytes)); gateway_var = g_variant_new_fixed_array (G_VARIANT_TYPE_BYTE, &gateway_bytes, 16, 1); g_variant_builder_add (&builder, "(@ayu@ay)", ip_var, prefix, gateway_var); } } return g_variant_builder_end (&builder); } /** * nm_utils_ip6_addresses_from_variant: * @value: a #GVariant of type 'a(ayuay)' * @out_gateway: (out) (allow-none) (transfer full): on return, will contain the IP gateway * * Utility function to convert a #GVariant of type 'a(ayuay)' representing a * list of NetworkManager IPv6 addresses (which are tuples of address, prefix, * and gateway) into a #GPtrArray of #NMIPAddress objects. The "gateway" field * of the first address (if set) will be returned in @out_gateway; the "gateway" * fields of the other addresses are ignored. * * Returns: (transfer full) (element-type NMIPAddress): a newly allocated * #GPtrArray of #NMIPAddress objects **/ GPtrArray * nm_utils_ip6_addresses_from_variant (GVariant *value, char **out_gateway) { GVariantIter iter; GVariant *addr_var, *gateway_var; guint32 prefix; GPtrArray *addresses; g_return_val_if_fail (g_variant_is_of_type (value, G_VARIANT_TYPE ("a(ayuay)")), NULL); if (out_gateway) *out_gateway = NULL; g_variant_iter_init (&iter, value); addresses = g_ptr_array_new_with_free_func ((GDestroyNotify) nm_ip_address_unref); while (g_variant_iter_next (&iter, "(@ayu@ay)", &addr_var, &prefix, &gateway_var)) { NMIPAddress *addr; const struct in6_addr *addr_bytes, *gateway_bytes; gsize addr_len, gateway_len; GError *error = NULL; if ( !g_variant_is_of_type (addr_var, G_VARIANT_TYPE_BYTESTRING) || !g_variant_is_of_type (gateway_var, G_VARIANT_TYPE_BYTESTRING)) { g_warning ("%s: ignoring invalid IP6 address structure", __func__); goto next; } addr_bytes = g_variant_get_fixed_array (addr_var, &addr_len, 1); if (addr_len != 16) { g_warning ("%s: ignoring invalid IP6 address of length %d", __func__, (int) addr_len); goto next; } addr = nm_ip_address_new_binary (AF_INET6, addr_bytes, prefix, &error); if (addr) { g_ptr_array_add (addresses, addr); if (out_gateway && !*out_gateway) { gateway_bytes = g_variant_get_fixed_array (gateway_var, &gateway_len, 1); if (gateway_len != 16) { g_warning ("%s: ignoring invalid IP6 address of length %d", __func__, (int) gateway_len); goto next; } if (!IN6_IS_ADDR_UNSPECIFIED (gateway_bytes)) *out_gateway = g_strdup (nm_utils_inet6_ntop (gateway_bytes, NULL)); } } else { g_warning ("Ignoring invalid IP6 address: %s", error->message); g_clear_error (&error); } next: g_variant_unref (addr_var); g_variant_unref (gateway_var); } return addresses; } /** * nm_utils_ip6_routes_to_variant: * @routes: (element-type NMIPRoute): an array of #NMIPRoute objects * * Utility function to convert a #GPtrArray of #NMIPRoute objects representing * IPv6 routes into a #GVariant of type 'a(ayuayu)' representing an array of * NetworkManager IPv6 routes (which are tuples of route, prefix, next hop, and * metric). * * Returns: (transfer none): a new floating #GVariant representing @routes. **/ GVariant * nm_utils_ip6_routes_to_variant (GPtrArray *routes) { GVariantBuilder builder; int i; g_variant_builder_init (&builder, G_VARIANT_TYPE ("a(ayuayu)")); if (routes) { for (i = 0; i < routes->len; i++) { NMIPRoute *route = routes->pdata[i]; struct in6_addr dest_bytes, next_hop_bytes; GVariant *dest, *next_hop; guint32 prefix, metric; if (nm_ip_route_get_family (route) != AF_INET6) continue; nm_ip_route_get_dest_binary (route, &dest_bytes); dest = g_variant_new_fixed_array (G_VARIANT_TYPE_BYTE, &dest_bytes, 16, 1); prefix = nm_ip_route_get_prefix (route); nm_ip_route_get_next_hop_binary (route, &next_hop_bytes); next_hop = g_variant_new_fixed_array (G_VARIANT_TYPE_BYTE, &next_hop_bytes, 16, 1); /* The old routes format uses "0" for default, not "-1" */ metric = MAX (0, nm_ip_route_get_metric (route)); g_variant_builder_add (&builder, "(@ayu@ayu)", dest, prefix, next_hop, metric); } } return g_variant_builder_end (&builder); } /** * nm_utils_ip6_routes_from_variant: * @value: #GVariant of type 'a(ayuayu)' * * Utility function to convert a #GVariant of type 'a(ayuayu)' representing an * array of NetworkManager IPv6 routes (which are tuples of route, prefix, next * hop, and metric) into a #GPtrArray of #NMIPRoute objects. * * Returns: (transfer full) (element-type NMIPRoute): a newly allocated * #GPtrArray of #NMIPRoute objects **/ GPtrArray * nm_utils_ip6_routes_from_variant (GVariant *value) { GPtrArray *routes; GVariantIter iter; GVariant *dest_var, *next_hop_var; const struct in6_addr *dest, *next_hop; gsize dest_len, next_hop_len; guint32 prefix, metric; g_return_val_if_fail (g_variant_is_of_type (value, G_VARIANT_TYPE ("a(ayuayu)")), NULL); routes = g_ptr_array_new_with_free_func ((GDestroyNotify) nm_ip_route_unref); g_variant_iter_init (&iter, value); while (g_variant_iter_next (&iter, "(@ayu@ayu)", &dest_var, &prefix, &next_hop_var, &metric)) { NMIPRoute *route; GError *error = NULL; if ( !g_variant_is_of_type (dest_var, G_VARIANT_TYPE_BYTESTRING) || !g_variant_is_of_type (next_hop_var, G_VARIANT_TYPE_BYTESTRING)) { g_warning ("%s: ignoring invalid IP6 address structure", __func__); goto next; } dest = g_variant_get_fixed_array (dest_var, &dest_len, 1); if (dest_len != 16) { g_warning ("%s: ignoring invalid IP6 address of length %d", __func__, (int) dest_len); goto next; } next_hop = g_variant_get_fixed_array (next_hop_var, &next_hop_len, 1); if (next_hop_len != 16) { g_warning ("%s: ignoring invalid IP6 address of length %d", __func__, (int) next_hop_len); goto next; } route = nm_ip_route_new_binary (AF_INET6, dest, prefix, next_hop, metric ? (gint64) metric : -1, &error); if (route) g_ptr_array_add (routes, route); else { g_warning ("Ignoring invalid IP6 route: %s", error->message); g_clear_error (&error); } next: g_variant_unref (dest_var); g_variant_unref (next_hop_var); } return routes; } /** * nm_utils_ip_addresses_to_variant: * @addresses: (element-type NMIPAddress): an array of #NMIPAddress objects * * Utility function to convert a #GPtrArray of #NMIPAddress objects representing * IPv4 or IPv6 addresses into a #GVariant of type 'aa{sv}' representing an * array of new-style NetworkManager IP addresses. All addresses will include * "address" (an IP address string), and "prefix" (a uint). Some addresses may * include additional attributes. * * Returns: (transfer none): a new floating #GVariant representing @addresses. **/ GVariant * nm_utils_ip_addresses_to_variant (GPtrArray *addresses) { GVariantBuilder builder; int i; g_variant_builder_init (&builder, G_VARIANT_TYPE ("aa{sv}")); if (addresses) { for (i = 0; i < addresses->len; i++) { NMIPAddress *addr = addresses->pdata[i]; GVariantBuilder addr_builder; char **names; int n; g_variant_builder_init (&addr_builder, G_VARIANT_TYPE ("a{sv}")); g_variant_builder_add (&addr_builder, "{sv}", "address", g_variant_new_string (nm_ip_address_get_address (addr))); g_variant_builder_add (&addr_builder, "{sv}", "prefix", g_variant_new_uint32 (nm_ip_address_get_prefix (addr))); names = nm_ip_address_get_attribute_names (addr); for (n = 0; names[n]; n++) { g_variant_builder_add (&addr_builder, "{sv}", names[n], nm_ip_address_get_attribute (addr, names[n])); } g_strfreev (names); g_variant_builder_add (&builder, "a{sv}", &addr_builder); } } return g_variant_builder_end (&builder); } /** * nm_utils_ip_addresses_from_variant: * @value: a #GVariant of type 'aa{sv}' * @family: an IP address family * * Utility function to convert a #GVariant representing a list of new-style * NetworkManager IPv4 or IPv6 addresses (as described in the documentation for * nm_utils_ip_addresses_to_variant()) into a #GPtrArray of #NMIPAddress * objects. * * Returns: (transfer full) (element-type NMIPAddress): a newly allocated * #GPtrArray of #NMIPAddress objects **/ GPtrArray * nm_utils_ip_addresses_from_variant (GVariant *value, int family) { GPtrArray *addresses; GVariantIter iter, attrs_iter; GVariant *addr_var; const char *ip; guint32 prefix; const char *attr_name; GVariant *attr_val; NMIPAddress *addr; GError *error = NULL; g_return_val_if_fail (g_variant_is_of_type (value, G_VARIANT_TYPE ("aa{sv}")), NULL); g_variant_iter_init (&iter, value); addresses = g_ptr_array_new_with_free_func ((GDestroyNotify) nm_ip_address_unref); while (g_variant_iter_next (&iter, "@a{sv}", &addr_var)) { if ( !g_variant_lookup (addr_var, "address", "&s", &ip) || !g_variant_lookup (addr_var, "prefix", "u", &prefix)) { g_warning ("Ignoring invalid address"); g_variant_unref (addr_var); continue; } addr = nm_ip_address_new (family, ip, prefix, &error); if (!addr) { g_warning ("Ignoring invalid address: %s", error->message); g_clear_error (&error); g_variant_unref (addr_var); continue; } g_variant_iter_init (&attrs_iter, addr_var); while (g_variant_iter_next (&attrs_iter, "{&sv}", &attr_name, &attr_val)) { if ( strcmp (attr_name, "address") != 0 && strcmp (attr_name, "prefix") != 0) nm_ip_address_set_attribute (addr, attr_name, attr_val); g_variant_unref (attr_val); } g_variant_unref (addr_var); g_ptr_array_add (addresses, addr); } return addresses; } /** * nm_utils_ip_routes_to_variant: * @routes: (element-type NMIPRoute): an array of #NMIPRoute objects * * Utility function to convert a #GPtrArray of #NMIPRoute objects representing * IPv4 or IPv6 routes into a #GVariant of type 'aa{sv}' representing an array * of new-style NetworkManager IP routes (which are tuples of destination, * prefix, next hop, metric, and additional attributes). * * Returns: (transfer none): a new floating #GVariant representing @routes. **/ GVariant * nm_utils_ip_routes_to_variant (GPtrArray *routes) { GVariantBuilder builder; int i; g_variant_builder_init (&builder, G_VARIANT_TYPE ("aa{sv}")); if (routes) { for (i = 0; i < routes->len; i++) { NMIPRoute *route = routes->pdata[i]; GVariantBuilder route_builder; char **names; int n; g_variant_builder_init (&route_builder, G_VARIANT_TYPE ("a{sv}")); g_variant_builder_add (&route_builder, "{sv}", "dest", g_variant_new_string (nm_ip_route_get_dest (route))); g_variant_builder_add (&route_builder, "{sv}", "prefix", g_variant_new_uint32 (nm_ip_route_get_prefix (route))); if (nm_ip_route_get_next_hop (route)) { g_variant_builder_add (&route_builder, "{sv}", "next-hop", g_variant_new_string (nm_ip_route_get_next_hop (route))); } if (nm_ip_route_get_metric (route) != -1) { g_variant_builder_add (&route_builder, "{sv}", "metric", g_variant_new_uint32 ((guint32) nm_ip_route_get_metric (route))); } names = nm_ip_route_get_attribute_names (route); for (n = 0; names[n]; n++) { g_variant_builder_add (&route_builder, "{sv}", names[n], nm_ip_route_get_attribute (route, names[n])); } g_strfreev (names); g_variant_builder_add (&builder, "a{sv}", &route_builder); } } return g_variant_builder_end (&builder); } /** * nm_utils_ip_routes_from_variant: * @value: a #GVariant of type 'aa{sv}' * @family: an IP address family * * Utility function to convert a #GVariant representing a list of new-style * NetworkManager IPv4 or IPv6 addresses (which are tuples of destination, * prefix, next hop, metric, and additional attributes) into a #GPtrArray of * #NMIPRoute objects. * * Returns: (transfer full) (element-type NMIPRoute): a newly allocated * #GPtrArray of #NMIPRoute objects **/ GPtrArray * nm_utils_ip_routes_from_variant (GVariant *value, int family) { GPtrArray *routes; GVariantIter iter, attrs_iter; GVariant *route_var; const char *dest, *next_hop; guint32 prefix, metric32; gint64 metric; const char *attr_name; GVariant *attr_val; NMIPRoute *route; GError *error = NULL; g_return_val_if_fail (g_variant_is_of_type (value, G_VARIANT_TYPE ("aa{sv}")), NULL); g_variant_iter_init (&iter, value); routes = g_ptr_array_new_with_free_func ((GDestroyNotify) nm_ip_route_unref); while (g_variant_iter_next (&iter, "@a{sv}", &route_var)) { if ( !g_variant_lookup (route_var, "dest", "&s", &dest) || !g_variant_lookup (route_var, "prefix", "u", &prefix)) { g_warning ("Ignoring invalid address"); goto next; } if (!g_variant_lookup (route_var, "next-hop", "&s", &next_hop)) next_hop = NULL; if (g_variant_lookup (route_var, "metric", "u", &metric32)) metric = metric32; else metric = -1; route = nm_ip_route_new (family, dest, prefix, next_hop, metric, &error); if (!route) { g_warning ("Ignoring invalid route: %s", error->message); g_clear_error (&error); goto next; } g_variant_iter_init (&attrs_iter, route_var); while (g_variant_iter_next (&attrs_iter, "{&sv}", &attr_name, &attr_val)) { if ( strcmp (attr_name, "dest") != 0 && strcmp (attr_name, "prefix") != 0 && strcmp (attr_name, "next-hop") != 0 && strcmp (attr_name, "metric") != 0) nm_ip_route_set_attribute (route, attr_name, attr_val); g_variant_unref (attr_val); } g_ptr_array_add (routes, route); next: g_variant_unref (route_var); } return routes; } /**********************************************************************************************/ /** * nm_utils_uuid_generate: * * Returns: a newly allocated UUID suitable for use as the #NMSettingConnection * object's #NMSettingConnection:id: property. Should be freed with g_free() **/ char * nm_utils_uuid_generate (void) { uuid_t uuid; char *buf; buf = g_malloc0 (37); uuid_generate_random (uuid); uuid_unparse_lower (uuid, &buf[0]); return buf; } /** * nm_utils_uuid_generate_from_string: * @s: a string to use as the seed for the UUID * @slen: if negative, treat @s as zero terminated C string. * Otherwise, assume the length as given (and allow @s to be * non-null terminated or contain '\0'). * @uuid_type: a type identifier which UUID format to generate. * @type_args: additional arguments, depending on the uuid_type * * For a given @s, this function will always return the same UUID. * * Returns: a newly allocated UUID suitable for use as the #NMSettingConnection * object's #NMSettingConnection:id: property **/ char * nm_utils_uuid_generate_from_string (const char *s, gssize slen, int uuid_type, gpointer type_args) { uuid_t uuid; char *buf; g_return_val_if_fail (slen == 0 || s, FALSE); g_return_val_if_fail (uuid_type == NM_UTILS_UUID_TYPE_LEGACY || uuid_type == NM_UTILS_UUID_TYPE_VARIANT3, NULL); g_return_val_if_fail (!type_args || uuid_type == NM_UTILS_UUID_TYPE_VARIANT3, NULL); switch (uuid_type) { case NM_UTILS_UUID_TYPE_LEGACY: crypto_md5_hash (NULL, 0, s, slen, (char *) uuid, sizeof (uuid)); break; case NM_UTILS_UUID_TYPE_VARIANT3: { uuid_t ns_uuid = { 0 }; if (type_args) { /* type_args can be a name space UUID. Interpret it as (char *) */ if (uuid_parse ((char *) type_args, ns_uuid) != 0) g_return_val_if_reached (NULL); } crypto_md5_hash (s, slen, (char *) ns_uuid, sizeof (ns_uuid), (char *) uuid, sizeof (uuid)); uuid[6] = (uuid[6] & 0x0F) | 0x30; uuid[8] = (uuid[8] & 0x3F) | 0x80; break; } default: g_return_val_if_reached (NULL); } buf = g_malloc0 (37); uuid_unparse_lower (uuid, &buf[0]); return buf; } /** * _nm_utils_uuid_generate_from_strings: * @string1: a variadic list of strings. Must be NULL terminated. * * Returns a variant3 UUID based on the concatenated C strings. * It does not simply concatenate them, but also includes the * terminating '\0' character. For example "a", "b", gives * "a\0b\0". * * This has the advantage, that the following invocations * all give different UUIDs: (NULL), (""), ("",""), ("","a"), ("a",""), * ("aa"), ("aa", ""), ("", "aa"), ... */ char * _nm_utils_uuid_generate_from_strings (const char *string1, ...) { GString *str; va_list args; const char *s; char *uuid; if (!string1) return nm_utils_uuid_generate_from_string (NULL, 0, NM_UTILS_UUID_TYPE_VARIANT3, NM_UTILS_UUID_NS); str = g_string_sized_new (120); /* effectively allocates power of 2 (128)*/ g_string_append_len (str, string1, strlen (string1) + 1); va_start (args, string1); s = va_arg (args, const char *); while (s) { g_string_append_len (str, s, strlen (s) + 1); s = va_arg (args, const char *); } va_end (args); uuid = nm_utils_uuid_generate_from_string (str->str, str->len, NM_UTILS_UUID_TYPE_VARIANT3, NM_UTILS_UUID_NS); g_string_free (str, TRUE); return uuid; } /**********************************************************************************************/ /** * nm_utils_rsa_key_encrypt: * @data: (array length=len): RSA private key data to be encrypted * @len: length of @data * @in_password: (allow-none): existing password to use, if any * @out_password: (out) (allow-none): if @in_password was %NULL, a random * password will be generated and returned in this argument * @error: detailed error information on return, if an error occurred * * Encrypts the given RSA private key data with the given password (or generates * a password if no password was given) and converts the data to PEM format * suitable for writing to a file. It uses Triple DES cipher for the encryption. * * Returns: (transfer full): on success, PEM-formatted data suitable for writing * to a PEM-formatted certificate/private key file. **/ GByteArray * nm_utils_rsa_key_encrypt (const guint8 *data, gsize len, const char *in_password, char **out_password, GError **error) { char salt[16]; int salt_len; char *key = NULL, *enc = NULL, *pw_buf[32]; gsize key_len = 0, enc_len = 0; GString *pem = NULL; char *tmp, *tmp_password = NULL; int left; const char *p; GByteArray *ret = NULL; g_return_val_if_fail (data != NULL, NULL); g_return_val_if_fail (len > 0, NULL); if (out_password) g_return_val_if_fail (*out_password == NULL, NULL); /* Make the password if needed */ if (!in_password) { if (!crypto_randomize (pw_buf, sizeof (pw_buf), error)) return NULL; in_password = tmp_password = nm_utils_bin2hexstr (pw_buf, sizeof (pw_buf), -1); } salt_len = 8; if (!crypto_randomize (salt, salt_len, error)) goto out; key = crypto_make_des_aes_key (CIPHER_DES_EDE3_CBC, &salt[0], salt_len, in_password, &key_len, NULL); if (!key) g_return_val_if_reached (NULL); enc = crypto_encrypt (CIPHER_DES_EDE3_CBC, data, len, salt, salt_len, key, key_len, &enc_len, error); if (!enc) goto out; pem = g_string_sized_new (enc_len * 2 + 100); g_string_append (pem, "-----BEGIN RSA PRIVATE KEY-----\n"); g_string_append (pem, "Proc-Type: 4,ENCRYPTED\n"); /* Convert the salt to a hex string */ tmp = nm_utils_bin2hexstr (salt, salt_len, salt_len * 2); g_string_append_printf (pem, "DEK-Info: %s,%s\n\n", CIPHER_DES_EDE3_CBC, tmp); g_free (tmp); /* Convert the encrypted key to a base64 string */ p = tmp = g_base64_encode ((const guchar *) enc, enc_len); left = strlen (tmp); while (left > 0) { g_string_append_len (pem, p, (left < 64) ? left : 64); g_string_append_c (pem, '\n'); left -= 64; p += 64; } g_free (tmp); g_string_append (pem, "-----END RSA PRIVATE KEY-----\n"); ret = g_byte_array_sized_new (pem->len); g_byte_array_append (ret, (const unsigned char *) pem->str, pem->len); if (tmp_password && out_password) *out_password = g_strdup (tmp_password); out: if (key) { memset (key, 0, key_len); g_free (key); } if (enc) { memset (enc, 0, enc_len); g_free (enc); } if (pem) g_string_free (pem, TRUE); if (tmp_password) { memset (tmp_password, 0, strlen (tmp_password)); g_free (tmp_password); } return ret; } static gboolean file_has_extension (const char *filename, const char *extensions[]) { const char *ext; int i; ext = strrchr (filename, '.'); if (!ext) return FALSE; for (i = 0; extensions[i]; i++) { if (!g_ascii_strcasecmp (ext, extensions[i])) return TRUE; } return FALSE; } /** * nm_utils_file_is_certificate: * @filename: name of the file to test * * Tests if @filename has a valid extension for an X.509 certificate file * (".cer", ".crt", ".der", or ".pem"), and contains a certificate in a format * recognized by NetworkManager. * * Returns: %TRUE if the file is a certificate, %FALSE if it is not **/ gboolean nm_utils_file_is_certificate (const char *filename) { const char *extensions[] = { ".der", ".pem", ".crt", ".cer", NULL }; NMCryptoFileFormat file_format = NM_CRYPTO_FILE_FORMAT_UNKNOWN; GByteArray *cert; g_return_val_if_fail (filename != NULL, FALSE); if (!file_has_extension (filename, extensions)) return FALSE; cert = crypto_load_and_verify_certificate (filename, &file_format, NULL); if (cert) g_byte_array_unref (cert); return file_format = NM_CRYPTO_FILE_FORMAT_X509; } /** * nm_utils_file_is_private_key: * @filename: name of the file to test * @out_encrypted: (out): on return, whether the file is encrypted * * Tests if @filename has a valid extension for an X.509 private key file * (".der", ".key", ".pem", or ".p12"), and contains a private key in a format * recognized by NetworkManager. * * Returns: %TRUE if the file is a private key, %FALSE if it is not **/ gboolean nm_utils_file_is_private_key (const char *filename, gboolean *out_encrypted) { const char *extensions[] = { ".der", ".pem", ".p12", ".key", NULL }; g_return_val_if_fail (filename != NULL, FALSE); NM_SET_OUT (out_encrypted, FALSE); if (!file_has_extension (filename, extensions)) return FALSE; return crypto_verify_private_key (filename, NULL, out_encrypted, NULL) != NM_CRYPTO_FILE_FORMAT_UNKNOWN; } /** * nm_utils_file_is_pkcs12: * @filename: name of the file to test * * Tests if @filename is a PKCS#12 file. * * Returns: %TRUE if the file is PKCS#12, %FALSE if it is not **/ gboolean nm_utils_file_is_pkcs12 (const char *filename) { g_return_val_if_fail (filename != NULL, FALSE); return crypto_is_pkcs12_file (filename, NULL); } /**********************************************************************************************/ gboolean _nm_utils_check_file (const char *filename, gint64 check_owner, NMUtilsCheckFilePredicate check_file, gpointer user_data, struct stat *out_st, GError **error) { struct stat st_backup; if (!out_st) out_st = &st_backup; if (stat (filename, out_st) != 0) { int errsv = errno; g_set_error (error, NM_VPN_PLUGIN_ERROR, NM_VPN_PLUGIN_ERROR_FAILED, _("failed stat file %s: %s"), filename, strerror (errsv)); return FALSE; } /* ignore non-files. */ if (!S_ISREG (out_st->st_mode)) { g_set_error (error, NM_VPN_PLUGIN_ERROR, NM_VPN_PLUGIN_ERROR_FAILED, _("not a file (%s)"), filename); return FALSE; } /* with check_owner enabled, check that the file belongs to the * owner or root. */ if ( check_owner >= 0 && (out_st->st_uid != 0 && (gint64) out_st->st_uid != check_owner)) { g_set_error (error, NM_VPN_PLUGIN_ERROR, NM_VPN_PLUGIN_ERROR_FAILED, _("invalid file owner %d for %s"), out_st->st_uid, filename); return FALSE; } /* with check_owner enabled, check that the file cannot be modified * by other users (except root). */ if ( check_owner >= 0 && NM_FLAGS_ANY (out_st->st_mode, S_IWGRP | S_IWOTH | S_ISUID)) { g_set_error (error, NM_VPN_PLUGIN_ERROR, NM_VPN_PLUGIN_ERROR_FAILED, _("file permissions for %s"), filename); return FALSE; } if ( check_file && !check_file (filename, out_st, user_data, error)) { if (error && !*error) { g_set_error (error, NM_VPN_PLUGIN_ERROR, NM_VPN_PLUGIN_ERROR_FAILED, _("reject %s"), filename); } return FALSE; } return TRUE; } gboolean _nm_utils_check_module_file (const char *name, int check_owner, NMUtilsCheckFilePredicate check_file, gpointer user_data, GError **error) { if (!g_path_is_absolute (name)) { g_set_error (error, NM_VPN_PLUGIN_ERROR, NM_VPN_PLUGIN_ERROR_FAILED, _("path is not absolute (%s)"), name); return FALSE; } /* Set special error code if the file doesn't exist. * The VPN package might be split into separate packages, * so it could be correct that the plugin file is missing. * * Note that nm-applet checks for this error code to fail * gracefully. */ if (!g_file_test (name, G_FILE_TEST_EXISTS)) { g_set_error (error, G_FILE_ERROR, G_FILE_ERROR_NOENT, _("Plugin file does not exist (%s)"), name); return FALSE; } if (!g_file_test (name, G_FILE_TEST_IS_REGULAR)) { g_set_error (error, NM_VPN_PLUGIN_ERROR, NM_VPN_PLUGIN_ERROR_FAILED, _("Plugin is not a valid file (%s)"), name); return FALSE; } if (g_str_has_suffix (name, ".la")) { /* g_module_open() treats files that end with .la special. * We don't want to parse the libtool archive. Just error out. */ g_set_error (error, NM_VPN_PLUGIN_ERROR, NM_VPN_PLUGIN_ERROR_FAILED, _("libtool archives are not supported (%s)"), name); return FALSE; } return _nm_utils_check_file (name, check_owner, check_file, user_data, NULL, error); } /**********************************************************************************************/ /** * nm_utils_file_search_in_paths: * @progname: the helper program name, like "iptables" * Must be a non-empty string, without path separator (/). * @try_first: (allow-none): a custom path to try first before searching. * It is silently ignored if it is empty or not an absolute path. * @paths: (allow-none): a %NULL terminated list of search paths. * Can be empty or %NULL, in which case only @try_first is checked. * @file_test_flags: the flags passed to g_file_test() when searching * for @progname. Set it to 0 to skip the g_file_test(). * @predicate: (scope call): if given, pass the file name to this function * for additional checks. This check is performed after the check for * @file_test_flags. You cannot omit both @file_test_flags and @predicate. * @user_data: (closure): (allow-none): user data for @predicate function. * @error: (allow-none): on failure, set a "not found" error %G_IO_ERROR %G_IO_ERROR_NOT_FOUND. * * Searches for a @progname file in a list of search @paths. * * Returns: (transfer none): the full path to the helper, if found, or %NULL if not found. * The returned string is not owned by the caller, but later * invocations of the function might overwrite it. */ const char * nm_utils_file_search_in_paths (const char *progname, const char *try_first, const char *const *paths, GFileTest file_test_flags, NMUtilsFileSearchInPathsPredicate predicate, gpointer user_data, GError **error) { GString *tmp; const char *ret; g_return_val_if_fail (!error || !*error, NULL); g_return_val_if_fail (progname && progname[0] && !strchr (progname, '/'), NULL); g_return_val_if_fail (file_test_flags || predicate, NULL); /* Only consider @try_first if it is a valid, absolute path. This makes * it simpler to pass in a path from configure checks. */ if ( try_first && try_first[0] == '/' && (file_test_flags == 0 || g_file_test (try_first, file_test_flags)) && (!predicate || predicate (try_first, user_data))) return g_intern_string (try_first); if (!paths || !*paths) goto NOT_FOUND; tmp = g_string_sized_new (50); for (; *paths; paths++) { if (!*paths) continue; g_string_append (tmp, *paths); if (tmp->str[tmp->len - 1] != '/') g_string_append_c (tmp, '/'); g_string_append (tmp, progname); if ( (file_test_flags == 0 || g_file_test (tmp->str, file_test_flags)) && (!predicate || predicate (tmp->str, user_data))) { ret = g_intern_string (tmp->str); g_string_free (tmp, TRUE); return ret; } g_string_set_size (tmp, 0); } g_string_free (tmp, TRUE); NOT_FOUND: g_set_error (error, G_IO_ERROR, G_IO_ERROR_NOT_FOUND, _("Could not find \"%s\" binary"), progname); return NULL; } /**********************************************************************************************/ /* Band, channel/frequency stuff for wireless */ struct cf_pair { guint32 chan; guint32 freq; }; static struct cf_pair a_table[] = { /* A band */ { 7, 5035 }, { 8, 5040 }, { 9, 5045 }, { 11, 5055 }, { 12, 5060 }, { 16, 5080 }, { 34, 5170 }, { 36, 5180 }, { 38, 5190 }, { 40, 5200 }, { 42, 5210 }, { 44, 5220 }, { 46, 5230 }, { 48, 5240 }, { 50, 5250 }, { 52, 5260 }, { 56, 5280 }, { 58, 5290 }, { 60, 5300 }, { 64, 5320 }, { 100, 5500 }, { 104, 5520 }, { 108, 5540 }, { 112, 5560 }, { 116, 5580 }, { 120, 5600 }, { 124, 5620 }, { 128, 5640 }, { 132, 5660 }, { 136, 5680 }, { 140, 5700 }, { 149, 5745 }, { 152, 5760 }, { 153, 5765 }, { 157, 5785 }, { 160, 5800 }, { 161, 5805 }, { 165, 5825 }, { 183, 4915 }, { 184, 4920 }, { 185, 4925 }, { 187, 4935 }, { 188, 4945 }, { 192, 4960 }, { 196, 4980 }, { 0, -1 } }; static struct cf_pair bg_table[] = { /* B/G band */ { 1, 2412 }, { 2, 2417 }, { 3, 2422 }, { 4, 2427 }, { 5, 2432 }, { 6, 2437 }, { 7, 2442 }, { 8, 2447 }, { 9, 2452 }, { 10, 2457 }, { 11, 2462 }, { 12, 2467 }, { 13, 2472 }, { 14, 2484 }, { 0, -1 } }; /** * nm_utils_wifi_freq_to_channel: * @freq: frequency * * Utility function to translate a Wi-Fi frequency to its corresponding channel. * * Returns: the channel represented by the frequency or 0 **/ guint32 nm_utils_wifi_freq_to_channel (guint32 freq) { int i = 0; if (freq > 4900) { while (a_table[i].chan && (a_table[i].freq != freq)) i++; return a_table[i].chan; } else { while (bg_table[i].chan && (bg_table[i].freq != freq)) i++; return bg_table[i].chan; } return 0; } /** * nm_utils_wifi_channel_to_freq: * @channel: channel * @band: frequency band for wireless ("a" or "bg") * * Utility function to translate a Wi-Fi channel to its corresponding frequency. * * Returns: the frequency represented by the channel of the band, * or -1 when the freq is invalid, or 0 when the band * is invalid **/ guint32 nm_utils_wifi_channel_to_freq (guint32 channel, const char *band) { int i = 0; if (!strcmp (band, "a")) { while (a_table[i].chan && (a_table[i].chan != channel)) i++; return a_table[i].freq; } else if (!strcmp (band, "bg")) { while (bg_table[i].chan && (bg_table[i].chan != channel)) i++; return bg_table[i].freq; } return 0; } /** * nm_utils_wifi_find_next_channel: * @channel: current channel * @direction: whether going downward (0 or less) or upward (1 or more) * @band: frequency band for wireless ("a" or "bg") * * Utility function to find out next/previous Wi-Fi channel for a channel. * * Returns: the next channel in the specified direction or 0 **/ guint32 nm_utils_wifi_find_next_channel (guint32 channel, int direction, char *band) { size_t a_size = sizeof (a_table) / sizeof (struct cf_pair); size_t bg_size = sizeof (bg_table) / sizeof (struct cf_pair); struct cf_pair *pair = NULL; if (!strcmp (band, "a")) { if (channel < a_table[0].chan) return a_table[0].chan; if (channel > a_table[a_size - 2].chan) return a_table[a_size - 2].chan; pair = &a_table[0]; } else if (!strcmp (band, "bg")) { if (channel < bg_table[0].chan) return bg_table[0].chan; if (channel > bg_table[bg_size - 2].chan) return bg_table[bg_size - 2].chan; pair = &bg_table[0]; } else { g_assert_not_reached (); return 0; } while (pair->chan) { if (channel == pair->chan) return channel; if ((channel < (pair+1)->chan) && (channel > pair->chan)) { if (direction > 0) return (pair+1)->chan; else return pair->chan; } pair++; } return 0; } /** * nm_utils_wifi_is_channel_valid: * @channel: channel * @band: frequency band for wireless ("a" or "bg") * * Utility function to verify Wi-Fi channel validity. * * Returns: %TRUE or %FALSE **/ gboolean nm_utils_wifi_is_channel_valid (guint32 channel, const char *band) { struct cf_pair *table = NULL; int i = 0; if (!strcmp (band, "a")) table = a_table; else if (!strcmp (band, "bg")) table = bg_table; else return FALSE; while (table[i].chan && (table[i].chan != channel)) i++; if (table[i].chan != 0) return TRUE; else return FALSE; } static const guint * _wifi_freqs (gboolean bg_band) { static guint *freqs_2ghz = NULL; static guint *freqs_5ghz = NULL; guint *freqs; freqs = bg_band ? freqs_2ghz : freqs_5ghz; if (G_UNLIKELY (freqs == NULL)) { struct cf_pair *table; int i; table = bg_band ? bg_table : a_table; freqs = g_new0 (guint, bg_band ? G_N_ELEMENTS (bg_table) : G_N_ELEMENTS (a_table)); for (i = 0; table[i].chan; i++) freqs[i] = table[i].freq; freqs[i] = 0; if (bg_band) freqs_2ghz = freqs; else freqs_5ghz = freqs; } return freqs; } /** * nm_utils_wifi_2ghz_freqs: * * Utility function to return 2.4 GHz Wi-Fi frequencies (802.11bg band). * * Returns: zero-terminated array of frequencies numbers (in MHz) * * Since: 1.2 **/ const guint * nm_utils_wifi_2ghz_freqs (void) { return _wifi_freqs (TRUE); } NM_BACKPORT_SYMBOL (libnm_1_0_6, const guint *, nm_utils_wifi_2ghz_freqs, (void), ()); /** * nm_utils_wifi_5ghz_freqs: * * Utility function to return 5 GHz Wi-Fi frequencies (802.11a band). * * Returns: zero-terminated array of frequencies numbers (in MHz) * * Since: 1.2 **/ const guint * nm_utils_wifi_5ghz_freqs (void) { return _wifi_freqs (FALSE); } NM_BACKPORT_SYMBOL (libnm_1_0_6, const guint *, nm_utils_wifi_5ghz_freqs, (void), ()); /** * nm_utils_wifi_strength_bars: * @strength: the access point strength, from 0 to 100 * * Converts @strength into a 4-character-wide graphical representation of * strength suitable for printing to stdout. If the current locale and terminal * support it, this will use unicode graphics characters to represent * "bars". Otherwise it will use 0 to 4 asterisks. * * Returns: the graphical representation of the access point strength */ const char * nm_utils_wifi_strength_bars (guint8 strength) { static const char *strength_full, *strength_high, *strength_med, *strength_low, *strength_none; if (G_UNLIKELY (strength_full == NULL)) { gboolean can_show_graphics = TRUE; char *locale_str; if (!g_get_charset (NULL)) { /* Non-UTF-8 locale */ locale_str = g_locale_from_utf8 ("\342\226\202\342\226\204\342\226\206\342\226\210", -1, NULL, NULL, NULL); if (locale_str) g_free (locale_str); else can_show_graphics = FALSE; } /* The linux console font doesn't have these characters */ if (g_strcmp0 (g_getenv ("TERM"), "linux") == 0) can_show_graphics = FALSE; if (can_show_graphics) { strength_full = /* ▂▄▆█ */ "\342\226\202\342\226\204\342\226\206\342\226\210"; strength_high = /* ▂▄▆_ */ "\342\226\202\342\226\204\342\226\206_"; strength_med = /* ▂▄__ */ "\342\226\202\342\226\204__"; strength_low = /* ▂___ */ "\342\226\202___"; strength_none = /* ____ */ "____"; } else { strength_full = "****"; strength_high = "*** "; strength_med = "** "; strength_low = "* "; strength_none = " "; } } if (strength > 80) return strength_full; else if (strength > 55) return strength_high; else if (strength > 30) return strength_med; else if (strength > 5) return strength_low; else return strength_none; } /** * nm_utils_hwaddr_len: * @type: the type of address; either ARPHRD_ETHER or * ARPHRD_INFINIBAND * * Returns the length in octets of a hardware address of type @type. * * It is an error to call this function with any value other than * ARPHRD_ETHER or ARPHRD_INFINIBAND. * * Return value: the length. */ gsize nm_utils_hwaddr_len (int type) { g_return_val_if_fail (type == ARPHRD_ETHER || type == ARPHRD_INFINIBAND, 0); if (type == ARPHRD_ETHER) return ETH_ALEN; else if (type == ARPHRD_INFINIBAND) return INFINIBAND_ALEN; g_assert_not_reached (); } #define HEXVAL(c) ((c) <= '9' ? (c) - '0' : ((c) & 0x4F) - 'A' + 10) /** * nm_utils_hwaddr_atoba: * @asc: the ASCII representation of a hardware address * @length: the expected length in bytes of the result * * Parses @asc and converts it to binary form in a #GByteArray. See * nm_utils_hwaddr_aton() if you don't want a #GByteArray. * * Return value: (transfer full): a new #GByteArray, or %NULL if @asc couldn't * be parsed */ GByteArray * nm_utils_hwaddr_atoba (const char *asc, gsize length) { GByteArray *ba; g_return_val_if_fail (asc != NULL, NULL); g_return_val_if_fail (length > 0 && length <= NM_UTILS_HWADDR_LEN_MAX, NULL); ba = g_byte_array_sized_new (length); g_byte_array_set_size (ba, length); if (!nm_utils_hwaddr_aton (asc, ba->data, length)) { g_byte_array_unref (ba); return NULL; } return ba; } /** * nm_utils_hwaddr_aton: * @asc: the ASCII representation of a hardware address * @buffer: buffer to store the result into * @length: the expected length in bytes of the result and * the size of the buffer in bytes. * * Parses @asc and converts it to binary form in @buffer. * Bytes in @asc can be sepatared by colons (:), or hyphens (-), but not mixed. * * Return value: @buffer, or %NULL if @asc couldn't be parsed * or would be shorter or longer than @length. */ guint8 * nm_utils_hwaddr_aton (const char *asc, gpointer buffer, gsize length) { const char *in = asc; guint8 *out = (guint8 *)buffer; char delimiter = '\0'; g_return_val_if_fail (asc != NULL, NULL); g_return_val_if_fail (buffer != NULL, NULL); g_return_val_if_fail (length > 0 && length <= NM_UTILS_HWADDR_LEN_MAX, NULL); while (length && *in) { guint8 d1 = in[0], d2 = in[1]; if (!g_ascii_isxdigit (d1)) return NULL; /* If there's no leading zero (ie "aa:b:cc") then fake it */ if (d2 && g_ascii_isxdigit (d2)) { *out++ = (HEXVAL (d1) << 4) + HEXVAL (d2); in += 2; } else { /* Fake leading zero */ *out++ = (HEXVAL ('0') << 4) + HEXVAL (d1); in += 1; } length--; if (*in) { if (delimiter == '\0') { if (*in == ':' || *in == '-') delimiter = *in; else return NULL; } else { if (*in != delimiter) return NULL; } in++; } } if (length == 0 && !*in) return buffer; else return NULL; } static char * _bin2str (gconstpointer addr, gsize length, gboolean upper_case) { const guint8 *in = addr; char *out, *result; const char *LOOKUP = upper_case ? "0123456789ABCDEF" : "0123456789abcdef"; g_return_val_if_fail (addr != NULL, g_strdup ("")); g_return_val_if_fail (length > 0, g_strdup ("")); result = out = g_malloc (length * 3); while (length--) { guint8 v = *in++; *out++ = LOOKUP[v >> 4]; *out++ = LOOKUP[v & 0x0F]; if (length) *out++ = ':'; } *out = 0; return result; } /** * nm_utils_hwaddr_ntoa: * @addr: (type guint8) (array length=length): a binary hardware address * @length: the length of @addr * * Converts @addr to textual form. * * Return value: (transfer full): the textual form of @addr */ char * nm_utils_hwaddr_ntoa (gconstpointer addr, gsize length) { return _bin2str (addr, length, TRUE); } /** * _nm_utils_bin2str: * @addr: (type guint8) (array length=length): a binary hardware address * @length: the length of @addr * @upper_case: the case for the hexadecimal digits. * * Converts @addr to textual form. * * Return value: (transfer full): the textual form of @addr */ char * _nm_utils_bin2str (gconstpointer addr, gsize length, gboolean upper_case) { return _bin2str (addr, length, upper_case); } static int hwaddr_binary_len (const char *asc) { int octets = 1; if (!*asc) return 0; for (; *asc; asc++) { if (*asc == ':' || *asc == '-') octets++; } return octets; } /** * _nm_utils_hwaddr_length: * @asc: the ASCII representation of the hardware address * * Validates that @asc is a valid representation of a hardware * address up to (including) %NM_UTILS_HWADDR_LEN_MAX bytes. * * Returns: binary length of the hardware address @asc or * 0 on error. */ guint _nm_utils_hwaddr_length (const char *asc) { int l; if (!asc) return 0; l = hwaddr_binary_len (asc); if (l <= 0 || l > NM_UTILS_HWADDR_LEN_MAX) return 0; if (!nm_utils_hwaddr_valid (asc, l)) return 0; return l; } /** * nm_utils_hwaddr_valid: * @asc: the ASCII representation of a hardware address * @length: the length of address that @asc is expected to convert to * (or -1 to accept any length up to %NM_UTILS_HWADDR_LEN_MAX) * * Parses @asc to see if it is a valid hardware address of the given * length. * * Return value: %TRUE if @asc appears to be a valid hardware address * of the indicated length, %FALSE if not. */ gboolean nm_utils_hwaddr_valid (const char *asc, gssize length) { guint8 buf[NM_UTILS_HWADDR_LEN_MAX]; g_return_val_if_fail (asc != NULL, FALSE); g_return_val_if_fail (length == -1 || (length > 0 && length <= NM_UTILS_HWADDR_LEN_MAX), FALSE); if (length == -1) { length = hwaddr_binary_len (asc); if (length == 0 || length > NM_UTILS_HWADDR_LEN_MAX) return FALSE; } return nm_utils_hwaddr_aton (asc, buf, length) != NULL; } /** * nm_utils_hwaddr_canonical: * @asc: the ASCII representation of a hardware address * @length: the length of address that @asc is expected to convert to * (or -1 to accept any length up to %NM_UTILS_HWADDR_LEN_MAX) * * Parses @asc to see if it is a valid hardware address of the given * length, and if so, returns it in canonical form (uppercase, with * leading 0s as needed, and with colons rather than hyphens). * * Return value: (transfer full): the canonicalized address if @asc appears to * be a valid hardware address of the indicated length, %NULL if not. */ char * nm_utils_hwaddr_canonical (const char *asc, gssize length) { guint8 buf[NM_UTILS_HWADDR_LEN_MAX]; g_return_val_if_fail (asc != NULL, NULL); g_return_val_if_fail (length == -1 || (length > 0 && length <= NM_UTILS_HWADDR_LEN_MAX), NULL); if (length == -1) { length = hwaddr_binary_len (asc); if (length == 0 || length > NM_UTILS_HWADDR_LEN_MAX) return NULL; } if (nm_utils_hwaddr_aton (asc, buf, length) == NULL) return NULL; return nm_utils_hwaddr_ntoa (buf, length); } /* This is used to possibly canonicalize values passed to MAC address property * setters. Unlike nm_utils_hwaddr_canonical(), it accepts %NULL, and if you * pass it an invalid MAC address, it just returns that string rather than * returning %NULL (so that we can return a proper error from verify() later). */ char * _nm_utils_hwaddr_canonical_or_invalid (const char *mac, gssize length) { char *canonical; if (!mac) return NULL; canonical = nm_utils_hwaddr_canonical (mac, length); if (canonical) return canonical; else return g_strdup (mac); } /** * nm_utils_hwaddr_matches: * @hwaddr1: pointer to a binary or ASCII hardware address, or %NULL * @hwaddr1_len: size of @hwaddr1, or -1 if @hwaddr1 is ASCII * @hwaddr2: pointer to a binary or ASCII hardware address, or %NULL * @hwaddr2_len: size of @hwaddr2, or -1 if @hwaddr2 is ASCII * * Generalized hardware address comparison function. Tests if @hwaddr1 and * @hwaddr2 "equal" (or more precisely, "equivalent"), with several advantages * over a simple memcmp(): * * 1. If @hwaddr1_len or @hwaddr2_len is -1, then the corresponding address is * assumed to be ASCII rather than binary, and will be converted to binary * before being compared. * * 2. If @hwaddr1 or @hwaddr2 is %NULL, it is treated instead as though it was * a zero-filled buffer @hwaddr1_len or @hwaddr2_len bytes long. * * 3. If @hwaddr1 and @hwaddr2 are InfiniBand hardware addresses (that is, if * they are INFINIBAND_ALEN bytes long in binary form) * then only the last 8 bytes are compared, since those are the only bytes * that actually identify the hardware. (The other 12 bytes will change * depending on the configuration of the InfiniBand fabric that the device * is connected to.) * * If a passed-in ASCII hardware address cannot be parsed, or would parse to an * address larger than %NM_UTILS_HWADDR_LEN_MAX, then it will silently fail to * match. (This means that externally-provided address strings do not need to be * sanity-checked before comparing them against known good addresses; they are * guaranteed to not match if they are invalid.) * * Return value: %TRUE if @hwaddr1 and @hwaddr2 are equivalent, %FALSE if they are * different (or either of them is invalid). */ gboolean nm_utils_hwaddr_matches (gconstpointer hwaddr1, gssize hwaddr1_len, gconstpointer hwaddr2, gssize hwaddr2_len) { guint8 buf1[NM_UTILS_HWADDR_LEN_MAX], buf2[NM_UTILS_HWADDR_LEN_MAX]; if (hwaddr1_len == -1) { g_return_val_if_fail (hwaddr1 != NULL, FALSE); hwaddr1_len = hwaddr_binary_len (hwaddr1); if (hwaddr1_len == 0 || hwaddr1_len > NM_UTILS_HWADDR_LEN_MAX) return FALSE; if (!nm_utils_hwaddr_aton (hwaddr1, buf1, hwaddr1_len)) return FALSE; hwaddr1 = buf1; } else { g_return_val_if_fail (hwaddr1_len > 0 && hwaddr1_len <= NM_UTILS_HWADDR_LEN_MAX, FALSE); if (!hwaddr1) { memset (buf1, 0, hwaddr1_len); hwaddr1 = buf1; } } if (hwaddr2_len == -1) { g_return_val_if_fail (hwaddr2 != NULL, FALSE); if (!nm_utils_hwaddr_aton (hwaddr2, buf2, hwaddr1_len)) return FALSE; hwaddr2 = buf2; hwaddr2_len = hwaddr1_len; } else { g_return_val_if_fail (hwaddr2_len > 0 && hwaddr2_len <= NM_UTILS_HWADDR_LEN_MAX, FALSE); if (!hwaddr2) { memset (buf2, 0, hwaddr2_len); hwaddr2 = buf2; } } if (hwaddr1_len != hwaddr2_len) return FALSE; if (hwaddr1_len == INFINIBAND_ALEN) { hwaddr1 = (guint8 *)hwaddr1 + INFINIBAND_ALEN - 8; hwaddr2 = (guint8 *)hwaddr2 + INFINIBAND_ALEN - 8; hwaddr1_len = hwaddr2_len = 8; } return !memcmp (hwaddr1, hwaddr2, hwaddr1_len); } /*****************************************************************************/ static GVariant * _nm_utils_hwaddr_to_dbus_impl (const char *str) { guint8 buf[NM_UTILS_HWADDR_LEN_MAX]; int len; if (!str) return NULL; len = _nm_utils_hwaddr_length (str); if (len == 0) return NULL; if (!nm_utils_hwaddr_aton (str, buf, len)) return NULL; return g_variant_new_fixed_array (G_VARIANT_TYPE_BYTE, buf, len, 1); } GVariant * _nm_utils_hwaddr_cloned_get (NMSetting *setting, const char *property) { gs_free char *addr = NULL; nm_assert (nm_streq0 (property, "cloned-mac-address")); g_object_get (setting, "cloned-mac-address", &addr, NULL); return _nm_utils_hwaddr_to_dbus_impl (addr); } gboolean _nm_utils_hwaddr_cloned_set (NMSetting *setting, GVariant *connection_dict, const char *property, GVariant *value, NMSettingParseFlags parse_flags, GError **error) { gsize length; const guint8 *array; char *str; nm_assert (nm_streq0 (property, "cloned-mac-address")); if (!_nm_setting_use_legacy_property (setting, connection_dict, "cloned-mac-address", "assigned-mac-address")) return TRUE; length = 0; array = g_variant_get_fixed_array (value, &length, 1); if (!length) return TRUE; str = nm_utils_hwaddr_ntoa (array, length); g_object_set (setting, "cloned-mac-address", str, NULL); g_free (str); return TRUE; } gboolean _nm_utils_hwaddr_cloned_not_set (NMSetting *setting, GVariant *connection_dict, const char *property, NMSettingParseFlags parse_flags, GError **error) { nm_assert (nm_streq0 (property, "cloned-mac-address")); return TRUE; } GVariant * _nm_utils_hwaddr_cloned_data_synth (NMSetting *setting, NMConnection *connection, const char *property) { gs_free char *addr = NULL; nm_assert (nm_streq0 (property, "assigned-mac-address")); g_object_get (setting, "cloned-mac-address", &addr, NULL); /* Before introducing the extended "cloned-mac-address" (and its D-Bus * field "assigned-mac-address"), libnm's _nm_utils_hwaddr_to_dbus() * would drop invalid values as it was unable to serialize them. * * Now, we would like to send invalid values as "assigned-mac-address" * over D-Bus and let the server reject them. * * However, clients used to set the cloned-mac-address property * to "" and it just worked as the value was not serialized in * an ill form. * * To preserve that behavior, seralize "" as NULL. */ return addr && addr[0] ? g_variant_new_string (addr) : NULL; } gboolean _nm_utils_hwaddr_cloned_data_set (NMSetting *setting, GVariant *connection_dict, const char *property, GVariant *value, NMSettingParseFlags parse_flags, GError **error) { nm_assert (nm_streq0 (property, "assigned-mac-address")); if (_nm_setting_use_legacy_property (setting, connection_dict, "cloned-mac-address", "assigned-mac-address")) return TRUE; g_object_set (setting, "cloned-mac-address", nm_str_not_empty (g_variant_get_string (value, NULL)), NULL); return TRUE; } GVariant * _nm_utils_hwaddr_to_dbus (const GValue *prop_value) { return _nm_utils_hwaddr_to_dbus_impl (g_value_get_string (prop_value)); } void _nm_utils_hwaddr_from_dbus (GVariant *dbus_value, GValue *prop_value) { gsize length = 0; const guint8 *array = g_variant_get_fixed_array (dbus_value, &length, 1); char *str; str = length ? nm_utils_hwaddr_ntoa (array, length) : NULL; g_value_take_string (prop_value, str); } /*****************************************************************************/ static char * _split_word (char *s) { /* takes @s and truncates the string on the first white-space. * then it returns the first word afterwards (again seeking * over leading white-space). */ for (; s[0]; s++) { if (g_ascii_isspace (s[0])) { s[0] = '\0'; s++; while (g_ascii_isspace (s[0])) s++; return s; } } return s; } gboolean _nm_utils_generate_mac_address_mask_parse (const char *value, struct ether_addr *out_mask, struct ether_addr **out_ouis, gsize *out_ouis_len, GError **error) { gs_free char *s_free = NULL; char *s, *s_next; struct ether_addr mask; gs_unref_array GArray *ouis = NULL; g_return_val_if_fail (!error || !*error, FALSE); if (!value || !*value) { /* NULL and "" are valid values and both mean the default * "q */ if (out_mask) { memset (out_mask, 0, sizeof (*out_mask)); out_mask->ether_addr_octet[0] |= 0x02; } NM_SET_OUT (out_ouis, NULL); NM_SET_OUT (out_ouis_len, 0); return TRUE; } s_free = g_strdup (value); s = s_free; /* skip over leading whitespace */ while (g_ascii_isspace (s[0])) s++; /* parse the first mask */ s_next = _split_word (s); if (!nm_utils_hwaddr_aton (s, &mask, ETH_ALEN)) { g_set_error (error, NM_UTILS_ERROR, NM_UTILS_ERROR_UNKNOWN, _("not a valid ethernet MAC address for mask at position %lld"), (long long) (s - s_free)); return FALSE; } if (s_next[0]) { ouis = g_array_sized_new (FALSE, FALSE, sizeof (struct ether_addr), 4); do { s = s_next; s_next = _split_word (s); g_array_set_size (ouis, ouis->len + 1); if (!nm_utils_hwaddr_aton (s, &g_array_index (ouis, struct ether_addr, ouis->len - 1), ETH_ALEN)) { g_set_error (error, NM_UTILS_ERROR, NM_UTILS_ERROR_UNKNOWN, _("not a valid ethernet MAC address #%u at position %lld"), ouis->len, (long long) (s - s_free)); return FALSE; } } while (s_next[0]); } NM_SET_OUT (out_mask, mask); NM_SET_OUT (out_ouis_len, ouis ? ouis->len : 0); NM_SET_OUT (out_ouis, ouis ? ((struct ether_addr *) g_array_free (g_steal_pointer (&ouis), FALSE)) : NULL); return TRUE; } /*****************************************************************************/ /** * nm_utils_bin2hexstr: * @src: (type guint8) (array length=len): an array of bytes * @len: the length of the @src array * @final_len: an index where to cut off the returned string, or -1 * * Converts the byte array @src into a hexadecimal string. If @final_len is * greater than -1, the returned string is terminated at that index * (returned_string[final_len] == '\0'), * * Return value: (transfer full): the textual form of @bytes */ /* * Code originally by Alex Larsson and * copyright Red Hat, Inc. under terms of the LGPL. */ char * nm_utils_bin2hexstr (gconstpointer src, gsize len, int final_len) { static char hex_digits[] = "0123456789abcdef"; const guint8 *bytes = src; char *result; int i; gsize buflen = (len * 2) + 1; g_return_val_if_fail (bytes != NULL, NULL); g_return_val_if_fail (len > 0, NULL); g_return_val_if_fail (len < 4096, NULL); /* Arbitrary limit */ if (final_len > -1) g_return_val_if_fail (final_len < buflen, NULL); result = g_malloc0 (buflen); for (i = 0; i < len; i++) { result[2*i] = hex_digits[(bytes[i] >> 4) & 0xf]; result[2*i+1] = hex_digits[bytes[i] & 0xf]; } /* Cut converted key off at the correct length for this cipher type */ if (final_len > -1) result[final_len] = '\0'; else result[buflen - 1] = '\0'; return result; } /** * nm_utils_hexstr2bin: * @hex: a string of hexadecimal characters with optional ':' separators * * Converts a hexadecimal string @hex into an array of bytes. The optional * separator ':' may be used between single or pairs of hexadecimal characters, * eg "00:11" or "0:1". Any "0x" at the beginning of @hex is ignored. @hex * may not start or end with ':'. * * Return value: (transfer full): the converted bytes, or %NULL on error */ GBytes * nm_utils_hexstr2bin (const char *hex) { guint i = 0, x = 0; gs_free guint8 *c = NULL; int a, b; gboolean found_colon = FALSE; g_return_val_if_fail (hex != NULL, NULL); if (strncasecmp (hex, "0x", 2) == 0) hex += 2; found_colon = !!strchr (hex, ':'); c = g_malloc (strlen (hex) / 2 + 1); for (;;) { a = g_ascii_xdigit_value (hex[i++]); if (a < 0) return NULL; if (hex[i] && hex[i] != ':') { b = g_ascii_xdigit_value (hex[i++]); if (b < 0) return NULL; c[x++] = ((guint) a << 4) | ((guint) b); } else c[x++] = (guint) a; if (!hex[i]) break; if (hex[i] == ':') { if (!hex[i + 1]) { /* trailing ':' is invalid */ return NULL; } i++; } else if (found_colon) { /* If colons exist, they must delimit 1 or 2 hex chars */ return NULL; } } return g_bytes_new (c, x); } /** * nm_utils_iface_valid_name: * @name: Name of interface * * This function is a 1:1 copy of the kernel's interface validation * function in net/core/dev.c. * * Returns: %TRUE if interface name is valid, otherwise %FALSE is returned. */ gboolean nm_utils_iface_valid_name (const char *name) { g_return_val_if_fail (name != NULL, FALSE); if (*name == '\0') return FALSE; if (strlen (name) >= 16) return FALSE; if (!strcmp (name, ".") || !strcmp (name, "..")) return FALSE; while (*name) { if (*name == '/' || g_ascii_isspace (*name)) return FALSE; name++; } return TRUE; } /** * nm_utils_is_uuid: * @str: a string that might be a UUID * * Checks if @str is a UUID * * Returns: %TRUE if @str is a UUID, %FALSE if not */ gboolean nm_utils_is_uuid (const char *str) { const char *p = str; int num_dashes = 0; while (*p) { if (*p == '-') num_dashes++; else if (!g_ascii_isxdigit (*p)) return FALSE; p++; } if ((num_dashes == 4) && (p - str == 36)) return TRUE; /* Backwards compat for older configurations */ if ((num_dashes == 0) && (p - str == 40)) return TRUE; return FALSE; } static char _nm_utils_inet_ntop_buffer[NM_UTILS_INET_ADDRSTRLEN]; /** * nm_utils_inet4_ntop: (skip) * @inaddr: the address that should be converted to string. * @dst: the destination buffer, it must contain at least * INET_ADDRSTRLEN or %NM_UTILS_INET_ADDRSTRLEN * characters. If set to %NULL, it will return a pointer to an internal, static * buffer (shared with nm_utils_inet6_ntop()). Beware, that the internal * buffer will be overwritten with ever new call of nm_utils_inet4_ntop() or * nm_utils_inet6_ntop() that does not provied it's own @dst buffer. Also, * using the internal buffer is not thread safe. When in doubt, pass your own * @dst buffer to avoid these issues. * * Wrapper for inet_ntop. * * Returns: the input buffer @dst, or a pointer to an * internal, static buffer. This function cannot fail. **/ const char * nm_utils_inet4_ntop (in_addr_t inaddr, char *dst) { return inet_ntop (AF_INET, &inaddr, dst ? dst : _nm_utils_inet_ntop_buffer, INET_ADDRSTRLEN); } /** * nm_utils_inet6_ntop: (skip) * @in6addr: the address that should be converted to string. * @dst: the destination buffer, it must contain at least * INET6_ADDRSTRLEN or %NM_UTILS_INET_ADDRSTRLEN * characters. If set to %NULL, it will return a pointer to an internal, static * buffer (shared with nm_utils_inet4_ntop()). Beware, that the internal * buffer will be overwritten with ever new call of nm_utils_inet4_ntop() or * nm_utils_inet6_ntop() that does not provied it's own @dst buffer. Also, * using the internal buffer is not thread safe. When in doubt, pass your own * @dst buffer to avoid these issues. * * Wrapper for inet_ntop. * * Returns: the input buffer @dst, or a pointer to an * internal, static buffer. %NULL is not allowed as @in6addr, * otherwise, this function cannot fail. **/ const char * nm_utils_inet6_ntop (const struct in6_addr *in6addr, char *dst) { g_return_val_if_fail (in6addr, NULL); return inet_ntop (AF_INET6, in6addr, dst ? dst : _nm_utils_inet_ntop_buffer, INET6_ADDRSTRLEN); } /** * nm_utils_ipaddr_valid: * @family: AF_INET or AF_INET6, or * AF_UNSPEC to accept either * @ip: an IP address * * Checks if @ip contains a valid IP address of the given family. * * Return value: %TRUE or %FALSE */ gboolean nm_utils_ipaddr_valid (int family, const char *ip) { guint8 buf[sizeof (struct in6_addr)]; g_return_val_if_fail (family == AF_INET || family == AF_INET6 || family == AF_UNSPEC, FALSE); if (!ip) return FALSE; if (family == AF_UNSPEC) family = strchr (ip, ':') ? AF_INET6 : AF_INET; return inet_pton (family, ip, buf) == 1; } /** * nm_utils_iinet6_is_token: * @in6addr: the AF_INET6 address structure * * Checks if only the bottom 64bits of the address are set. * * Return value: %TRUE or %FALSE */ gboolean _nm_utils_inet6_is_token (const struct in6_addr *in6addr) { if ( in6addr->s6_addr[0] || in6addr->s6_addr[1] || in6addr->s6_addr[2] || in6addr->s6_addr[3] || in6addr->s6_addr[4] || in6addr->s6_addr[5] || in6addr->s6_addr[6] || in6addr->s6_addr[7]) return FALSE; if ( in6addr->s6_addr[8] || in6addr->s6_addr[9] || in6addr->s6_addr[10] || in6addr->s6_addr[11] || in6addr->s6_addr[12] || in6addr->s6_addr[13] || in6addr->s6_addr[14] || in6addr->s6_addr[15]) return TRUE; return FALSE; } /** * nm_utils_check_virtual_device_compatibility: * @virtual_type: a virtual connection type * @other_type: a connection type to test against @virtual_type * * Determines if a connection of type @virtual_type can (in the * general case) work with connections of type @other_type. * * If @virtual_type is %NM_TYPE_SETTING_VLAN, then this checks if * @other_type is a valid type for the parent of a VLAN. * * If @virtual_type is a "master" type (eg, %NM_TYPE_SETTING_BRIDGE), * then this checks if @other_type is a valid type for a slave of that * master. * * Note that even if this returns %TRUE it is not guaranteed that * every connection of type @other_type is * compatible with @virtual_type; it may depend on the exact * configuration of the two connections, or on the capabilities of an * underlying device driver. * * Returns: %TRUE or %FALSE */ gboolean nm_utils_check_virtual_device_compatibility (GType virtual_type, GType other_type) { g_return_val_if_fail (_nm_setting_type_is_base_type (virtual_type), FALSE); g_return_val_if_fail (_nm_setting_type_is_base_type (other_type), FALSE); if (virtual_type == NM_TYPE_SETTING_BOND) { return ( other_type == NM_TYPE_SETTING_INFINIBAND || other_type == NM_TYPE_SETTING_WIRED || other_type == NM_TYPE_SETTING_BRIDGE || other_type == NM_TYPE_SETTING_BOND || other_type == NM_TYPE_SETTING_TEAM || other_type == NM_TYPE_SETTING_VLAN); } else if (virtual_type == NM_TYPE_SETTING_BRIDGE) { return ( other_type == NM_TYPE_SETTING_WIRED || other_type == NM_TYPE_SETTING_BOND || other_type == NM_TYPE_SETTING_TEAM || other_type == NM_TYPE_SETTING_VLAN); } else if (virtual_type == NM_TYPE_SETTING_TEAM) { return ( other_type == NM_TYPE_SETTING_WIRED || other_type == NM_TYPE_SETTING_BRIDGE || other_type == NM_TYPE_SETTING_BOND || other_type == NM_TYPE_SETTING_TEAM || other_type == NM_TYPE_SETTING_VLAN); } else if (virtual_type == NM_TYPE_SETTING_VLAN) { return ( other_type == NM_TYPE_SETTING_WIRED || other_type == NM_TYPE_SETTING_WIRELESS || other_type == NM_TYPE_SETTING_BRIDGE || other_type == NM_TYPE_SETTING_BOND || other_type == NM_TYPE_SETTING_TEAM || other_type == NM_TYPE_SETTING_VLAN); } else { g_warn_if_reached (); return FALSE; } } typedef struct { const char *str; const char *num; } BondMode; static BondMode bond_mode_table[] = { [0] = { "balance-rr", "0" }, [1] = { "active-backup", "1" }, [2] = { "balance-xor", "2" }, [3] = { "broadcast", "3" }, [4] = { "802.3ad", "4" }, [5] = { "balance-tlb", "5" }, [6] = { "balance-alb", "6" }, }; /** * nm_utils_bond_mode_int_to_string: * @mode: bonding mode as a numeric value * * Convert bonding mode from integer value to descriptive name. * See https://www.kernel.org/doc/Documentation/networking/bonding.txt for * available modes. * * Returns: bonding mode string, or NULL on error * * Since: 1.2 */ const char * nm_utils_bond_mode_int_to_string (int mode) { if (mode >= 0 && mode < G_N_ELEMENTS (bond_mode_table)) return bond_mode_table[mode].str; return NULL; } /** * nm_utils_bond_mode_string_to_int: * @mode: bonding mode as string * * Convert bonding mode from string representation to numeric value. * See https://www.kernel.org/doc/Documentation/networking/bonding.txt for * available modes. * The @mode string can be either a descriptive name or a number (as string). * * Returns: numeric bond mode, or -1 on error * * Since: 1.2 */ int nm_utils_bond_mode_string_to_int (const char *mode) { int i; if (!mode || !*mode) return -1; for (i = 0; i < G_N_ELEMENTS (bond_mode_table); i++) { if ( strcmp (mode, bond_mode_table[i].str) == 0 || strcmp (mode, bond_mode_table[i].num) == 0) return i; } return -1; } /**********************************************************************************************/ #define STRSTRDICTKEY_V1_SET 0x01 #define STRSTRDICTKEY_V2_SET 0x02 #define STRSTRDICTKEY_ALL_SET 0x03 struct _NMUtilsStrStrDictKey { char type; char data[1]; }; guint _nm_utils_strstrdictkey_hash (gconstpointer a) { const NMUtilsStrStrDictKey *k = a; const signed char *p; guint32 h = 5381; if (k) { if (((int) k->type) & ~STRSTRDICTKEY_ALL_SET) g_return_val_if_reached (0); h = (h << 5) + h + k->type; if (k->type & STRSTRDICTKEY_ALL_SET) { p = (void *) k->data; for (; *p != '\0'; p++) h = (h << 5) + h + *p; if (k->type == STRSTRDICTKEY_ALL_SET) { /* the key contains two strings. Continue... */ h = (h << 5) + h + '\0'; for (p++; *p != '\0'; p++) h = (h << 5) + h + *p; } } } return h; } gboolean _nm_utils_strstrdictkey_equal (gconstpointer a, gconstpointer b) { const NMUtilsStrStrDictKey *k1 = a; const NMUtilsStrStrDictKey *k2 = b; if (k1 == k2) return TRUE; if (!k1 || !k2) return FALSE; if (k1->type != k2->type) return FALSE; if (k1->type & STRSTRDICTKEY_ALL_SET) { if (strcmp (k1->data, k2->data) != 0) return FALSE; if (k1->type == STRSTRDICTKEY_ALL_SET) { gsize l = strlen (k1->data) + 1; return strcmp (&k1->data[l], &k2->data[l]) == 0; } } return TRUE; } NMUtilsStrStrDictKey * _nm_utils_strstrdictkey_create (const char *v1, const char *v2) { char type = 0; gsize l1 = 0, l2 = 0; NMUtilsStrStrDictKey *k; if (!v1 && !v2) return g_malloc0 (1); /* we need to distinguish between ("",NULL) and (NULL,""). * Thus, in @type we encode which strings we have present * as not-NULL. */ if (v1) { type |= STRSTRDICTKEY_V1_SET; l1 = strlen (v1) + 1; } if (v2) { type |= STRSTRDICTKEY_V2_SET; l2 = strlen (v2) + 1; } k = g_malloc (G_STRUCT_OFFSET (NMUtilsStrStrDictKey, data) + l1 + l2); k->type = type; if (v1) memcpy (&k->data[0], v1, l1); if (v2) memcpy (&k->data[l1], v2, l2); return k; } static gboolean validate_dns_option (const char *name, gboolean numeric, gboolean ipv6, const NMUtilsDNSOptionDesc *option_descs) { const NMUtilsDNSOptionDesc *desc; if (!option_descs) return !!*name; for (desc = option_descs; desc->name; desc++) { if (!strcmp (name, desc->name) && numeric == desc->numeric && (!desc->ipv6_only || ipv6)) return TRUE; } return FALSE; } /** * _nm_utils_dns_option_validate: * @option: option string * @out_name: (out) (allow-none): the option name * @out_value: (out) (allow-none): the option value * @ipv6: whether the option refers to a IPv6 configuration * @option_descs: (allow-none): an array of NMUtilsDNSOptionDesc which describes the * valid options * * Parses a DNS option in the form "name" or "name:number" and, if * @option_descs is not NULL, checks that the option conforms to one * of the provided descriptors. If @option_descs is NULL @ipv6 is * not considered. * * Returns: %TRUE when the parsing was successful and the option is valid, * %FALSE otherwise */ gboolean _nm_utils_dns_option_validate (const char *option, char **out_name, long *out_value, gboolean ipv6, const NMUtilsDNSOptionDesc *option_descs) { char **tokens, *ptr; gboolean ret = FALSE; g_return_val_if_fail (option != NULL, FALSE); if (out_name) *out_name = NULL; if (out_value) *out_value = -1; if (!option[0]) return FALSE; tokens = g_strsplit (option, ":", 2); if (g_strv_length (tokens) == 1) { ret = validate_dns_option (tokens[0], FALSE, ipv6, option_descs); if (ret && out_name) *out_name = g_strdup (tokens[0]); goto out; } if (!tokens[1][0]) { ret = FALSE; goto out; } for (ptr = tokens[1]; *ptr; ptr++) { if (!g_ascii_isdigit (*ptr)) { ret = FALSE; goto out; } } ret = FALSE; if (validate_dns_option (tokens[0], TRUE, ipv6, option_descs)) { int value = _nm_utils_ascii_str_to_int64 (tokens[1], 10, 0, G_MAXINT32, -1); if (value >= 0) { if (out_name) *out_name = g_strdup (tokens[0]); if (out_value) *out_value = value; ret = TRUE; } } out: g_strfreev (tokens); return ret; } /** * _nm_utils_dns_option_find_idx: * @array: an array of strings * @option: a dns option string * * Searches for an option in an array of strings. The match is * performed only the option name; the option value is ignored. * * Returns: the index of the option in the array or -1 if was not * found. */ int _nm_utils_dns_option_find_idx (GPtrArray *array, const char *option) { gboolean ret; char *option_name, *tmp_name; int i; if (!_nm_utils_dns_option_validate (option, &option_name, NULL, FALSE, NULL)) return -1; for (i = 0; i < array->len; i++) { if (_nm_utils_dns_option_validate (array->pdata[i], &tmp_name, NULL, FALSE, NULL)) { ret = strcmp (tmp_name, option_name); g_free (tmp_name); if (!ret) { g_free (option_name); return i; } } } g_free (option_name); return -1; } /** * nm_utils_enum_to_str: * @type: the %GType of the enum * @value: the value to be translated * * Converts an enum value to its string representation. If the enum is a * %G_TYPE_FLAGS the function returns a comma-separated list of matching values. * If the enum is a %G_TYPE_ENUM and the given value is not valid the * function returns %NULL. * * Returns: a newly allocated string or %NULL * * Since: 1.2 */ char *nm_utils_enum_to_str (GType type, int value) { GTypeClass *class; char *ret; class = g_type_class_ref (type); if (G_IS_ENUM_CLASS (class)) { GEnumValue *enum_value; enum_value = g_enum_get_value (G_ENUM_CLASS (class), value); ret = enum_value ? strdup (enum_value->value_nick) : NULL; } else if (G_IS_FLAGS_CLASS (class)) { GFlagsValue *flags_value; GString *str = g_string_new (""); gboolean first = TRUE; while (value) { flags_value = g_flags_get_first_value (G_FLAGS_CLASS (class), value); if (!flags_value) break; if (!first) g_string_append (str, ", "); g_string_append (str, flags_value->value_nick); value &= ~flags_value->value; first = FALSE; } ret = g_string_free (str, FALSE); } else g_return_val_if_reached (NULL); g_type_class_unref (class); return ret; } NM_BACKPORT_SYMBOL (libnm_1_0_6, char *, nm_utils_enum_to_str, (GType type, int value), (type, value)); /** * nm_utils_enum_from_str: * @type: the %GType of the enum * @str: the input string * @out_value: (out) (allow-none): the output value * @err_token: (out) (allow-none): location to store the first unrecognized token * * Converts a string to the matching enum value. * * If the enum is a %G_TYPE_FLAGS the function returns the logical OR of values * matching the comma-separated tokens in the string; if an unknown token is found * the function returns %FALSE and stores a pointer to a newly allocated string * containing the unrecognized token in @err_token. * * Returns: %TRUE if the conversion was successful, %FALSE otherwise * * Since: 1.2 */ gboolean nm_utils_enum_from_str (GType type, const char *str, int *out_value, char **err_token) { GTypeClass *class; gboolean ret = FALSE; int value = 0; gs_free char *stripped = NULL; g_return_val_if_fail (str, FALSE); stripped = g_strstrip (strdup (str)); class = g_type_class_ref (type); if (G_IS_ENUM_CLASS (class)) { GEnumValue *enum_value; enum_value = g_enum_get_value_by_nick (G_ENUM_CLASS (class), stripped); if (enum_value) { value = enum_value->value; ret = TRUE; } } else if (G_IS_FLAGS_CLASS (class)) { GFlagsValue *flags_value; gs_strfreev char **strv = NULL; int i; strv = g_strsplit_set (stripped, " \t,", 0); for (i = 0; strv[i]; i++) { if (!strv[i][0]) continue; flags_value = g_flags_get_value_by_nick (G_FLAGS_CLASS (class), strv[i]); if (!flags_value) break; value |= flags_value->value; } if (strv[i]) { if (err_token) *err_token = strdup (strv[i]); value = 0; } else ret = TRUE; } else g_return_val_if_reached (FALSE); if (out_value) *out_value = value; g_type_class_unref (class); return ret; } NM_BACKPORT_SYMBOL (libnm_1_0_6, gboolean, nm_utils_enum_from_str, (GType type, const char *str, int *out_value, char **err_token), (type, str, out_value, err_token)); /** * nm_utils_enum_get_values: * @type: the %GType of the enum * @from: the first element to be returned * @to: the last element to be returned * * Returns the list of possible values for a given enum. * * Returns: (transfer full): a NULL-terminated dynamically-allocated array of static strings * or %NULL on error * * Since: 1.2 */ const char **nm_utils_enum_get_values (GType type, gint from, gint to) { GTypeClass *class; GPtrArray *array; gint i; class = g_type_class_ref (type); array = g_ptr_array_new (); if (G_IS_ENUM_CLASS (class)) { GEnumClass *enum_class = G_ENUM_CLASS (class); GEnumValue *enum_value; for (i = 0; i < enum_class->n_values; i++) { enum_value = &enum_class->values[i]; if (enum_value->value >= from && enum_value->value <= to) g_ptr_array_add (array, (gpointer) enum_value->value_nick); } } else if (G_IS_FLAGS_CLASS (class)) { GFlagsClass *flags_class = G_FLAGS_CLASS (class); GFlagsValue *flags_value; for (i = 0; i < flags_class->n_values; i++) { flags_value = &flags_class->values[i]; if (flags_value->value >= from && flags_value->value <= to) g_ptr_array_add (array, (gpointer) flags_value->value_nick); } } else { g_type_class_unref (class); g_ptr_array_free (array, TRUE); g_return_val_if_reached (NULL); } g_type_class_unref (class); g_ptr_array_add (array, NULL); return (const char **) g_ptr_array_free (array, FALSE); } #if WITH_JANSSON gboolean _nm_utils_check_valid_json (const char *str, GError **error) { json_t *json; json_error_t jerror; g_return_val_if_fail (!error || !*error, FALSE); if (!str || !str[0]) { g_set_error_literal (error, NM_CONNECTION_ERROR, NM_CONNECTION_ERROR_INVALID_PROPERTY, "value is NULL or empty"); return FALSE; } json = json_loads (str, 0, &jerror); if (!json) { g_set_error (error, NM_CONNECTION_ERROR, NM_CONNECTION_ERROR_INVALID_PROPERTY, "%s at position %d", jerror.text, jerror.position); return FALSE; } json_decref (json); return TRUE; } /* json_object_foreach_safe() is only available since Jansson 2.8, * reimplement it */ #define _json_object_foreach_safe(object, n, key, value) \ for (key = json_object_iter_key (json_object_iter (object)), \ n = json_object_iter_next (object, json_object_iter_at (object, key)); \ key && (value = json_object_iter_value (json_object_iter_at (object, key))); \ key = json_object_iter_key (n), \ n = json_object_iter_next (object, json_object_iter_at (object, key))) gboolean _nm_utils_team_config_equal (const char *conf1, const char *conf2, gboolean port_config) { json_t *json1 = NULL, *json2 = NULL, *json; gs_free char *dump1 = NULL, *dump2 = NULL; json_t *value, *property; json_error_t jerror; const char *key; gboolean ret; void *tmp; int i; if (nm_streq0 (conf1, conf2)) return TRUE; /* A NULL configuration is equivalent to default value '{}' */ json1 = json_loads (conf1 ?: "{}", 0, &jerror); if (json1) json2 = json_loads (conf2 ?: "{}", 0, &jerror); if (!json1 || !json2) { ret = FALSE; goto out; } /* Some properties are added by teamd when missing from the initial * configuration. Add them with the default value if necessary, depending * on the configuration type. */ for (i = 0, json = json1; i < 2; i++, json = json2) { if (port_config) { property = json_object_get (json, "link_watch"); if (!property) { property = json_object (); json_object_set_new (property, "name", json_string ("ethtool")); json_object_set_new (json, "link_watch", property); } } else { property = json_object_get (json, "runner"); if (!property) { property = json_object (); json_object_set_new (property, "name", json_string ("roundrobin")); json_object_set_new (json, "runner", property); } } } /* Only consider a given subset of nodes, others can change depending on * current state */ for (i = 0, json = json1; i < 2; i++, json = json2) { _json_object_foreach_safe (json, tmp, key, value) { if (!NM_IN_STRSET (key, "runner", "link_watch")) json_object_del (json, key); } } dump1 = json_dumps (json1, JSON_INDENT(0) | JSON_ENSURE_ASCII | JSON_SORT_KEYS); dump2 = json_dumps (json2, JSON_INDENT(0) | JSON_ENSURE_ASCII | JSON_SORT_KEYS); ret = nm_streq0 (dump1, dump2); out: if (json1) json_decref (json1); if (json2) json_decref (json2); return ret; } #else /* WITH_JANSSON */ gboolean _nm_utils_check_valid_json (const char *str, GError **error) { if (!str || !str[0]) { g_set_error_literal (error, NM_CONNECTION_ERROR, NM_CONNECTION_ERROR_INVALID_PROPERTY, "value is NULL or empty"); return FALSE; } return TRUE; } gboolean _nm_utils_team_config_equal (const char *conf1, const char *conf2, gboolean port_config) { return nm_streq0 (conf1, conf2); } #endif