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|
/* -*- 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 "config.h"
#include <string.h>
#include <stdlib.h>
#include <netinet/ether.h>
#include <arpa/inet.h>
#include <uuid/uuid.h>
#include <libintl.h>
#include <gmodule.h>
#include <glib/gi18n-lib.h>
#include "nm-utils.h"
#include "nm-utils-private.h"
#include "nm-glib-compat.h"
#include "nm-setting-private.h"
#include "crypto.h"
#include "gsystem-local-alloc.h"
#include "nm-utils-internal.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"
/* Embed the commit id in the build binary */
static const char *const __nm_git_sha = STRLEN (NM_GIT_SHA) > 0 ? "NM_GIT_SHA:"NM_GIT_SHA : "";
/**
* 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;
(void) __nm_git_sha;
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");
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);
}
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, "<hidden>", sizeof ("<hidden>"));
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;
}
gboolean
_nm_utils_string_in_list (const char *str, const char **valid_strings)
{
int i;
for (i = 0; valid_strings[i]; i++)
if (strcmp (str, valid_strings[i]) == 0)
break;
return valid_strings[i] != NULL;
}
gboolean
_nm_utils_string_slist_validate (GSList *list, const char **valid_values)
{
GSList *iter;
for (iter = list; iter; iter = iter->next) {
if (!_nm_utils_string_in_list ((char *) iter->data, valid_values))
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);
}
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)
{
int i;
GSList *list = NULL;
if (strv) {
for (i = 0; strv[i]; i++)
list = g_slist_prepend (list, g_strdup (strv[i]));
}
return g_slist_reverse (list);
}
char **
_nm_utils_slist_to_strv (GSList *slist)
{
GSList *iter;
char **strv;
int len, i;
len = g_slist_length (slist);
strv = g_new (char *, len + 1);
for (i = 0, iter = slist; iter; iter = iter->next, i++)
strv[i] = g_strdup (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_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;
keylen = strlen (key);
if ( wep_type == NM_WEP_KEY_TYPE_KEY
|| wep_type == NM_WEP_KEY_TYPE_UNKNOWN) {
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 IP4 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_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");
g_variant_unref (route_var);
continue;
}
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);
g_variant_unref (route_var);
continue;
}
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);
}
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_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);
g_return_val_if_fail (out_encrypted == NULL || *out_encrypted == FALSE, 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);
}
/**********************************************************************************************/
/**
* 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;
}
/**
* 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 <literal>ARPHRD_ETHER</literal> or
* <literal>ARPHRD_INFINIBAND</literal>
*
* 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
* <literal>ARPHRD_ETHER</literal> or <literal>ARPHRD_INFINIBAND</literal>.
*
* 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;
}
/**
* 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)
{
const guint8 *in = addr;
char *out, *result;
const char *LOOKUP = "0123456789ABCDEF";
g_return_val_if_fail (addr != NULL, g_strdup (""));
g_return_val_if_fail (length > 0 && length <= NM_UTILS_HWADDR_LEN_MAX, 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;
}
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_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 <literal>INFINIBAND_ALEN</literal> 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);
}
GVariant *
_nm_utils_hwaddr_to_dbus (const GValue *prop_value)
{
const char *str = g_value_get_string (prop_value);
guint8 buf[NM_UTILS_HWADDR_LEN_MAX];
int len;
if (str) {
len = hwaddr_binary_len (str);
g_return_val_if_fail (len > 0 && len <= NM_UTILS_HWADDR_LEN_MAX, NULL);
if (!nm_utils_hwaddr_aton (str, buf, len))
len = 0;
} else
len = 0;
return g_variant_new_fixed_array (G_VARIANT_TYPE_BYTE, buf, len, 1);
}
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);
}
/**
* 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 <alexl@redhat.com> 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
* <literal>INET_ADDRSTRLEN</literal> 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
* <literal>INET6_ADDRSTRLEN</literal> 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: <literal>AF_INET</literal> or <literal>AF_INET6</literal>, or
* <literal>AF_UNSPEC</literal> 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 (family == AF_UNSPEC)
family = strchr (ip, ':') ? AF_INET6 : AF_INET;
return inet_pton (family, ip, buf) == 1;
}
/**
* 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
* <emphasis>every</emphasis> 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;
}
|