tor/src/or/policies.c

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/* Copyright (c) 2001-2004, Roger Dingledine.
* Copyright (c) 2004-2006, Roger Dingledine, Nick Mathewson.
* Copyright (c) 2007-2015, The Tor Project, Inc. */
/* See LICENSE for licensing information */
/**
* \file policies.c
* \brief Code to parse and use address policies and exit policies.
**/
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#define POLICIES_PRIVATE
#include "or.h"
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#include "config.h"
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#include "dirserv.h"
#include "networkstatus.h"
Initial conversion to use node_t throughout our codebase. A node_t is an abstraction over routerstatus_t, routerinfo_t, and microdesc_t. It should try to present a consistent interface to all of them. There should be a node_t for a server whenever there is * A routerinfo_t for it in the routerlist * A routerstatus_t in the current_consensus. (note that a microdesc_t alone isn't enough to make a node_t exist, since microdescriptors aren't usable on their own.) There are three ways to get a node_t right now: looking it up by ID, looking it up by nickname, and iterating over the whole list of microdescriptors. All (or nearly all) functions that are supposed to return "a router" -- especially those used in building connections and circuits -- should return a node_t, not a routerinfo_t or a routerstatus_t. A node_t should hold all the *mutable* flags about a node. This patch moves the is_foo flags from routerinfo_t into node_t. The flags in routerstatus_t remain, but they get set from the consensus and should not change. Some other highlights of this patch are: * Looking up routerinfo and routerstatus by nickname is now unified and based on the "look up a node by nickname" function. This tries to look only at the values from current consensus, and not get confused by the routerinfo_t->is_named flag, which could get set for other weird reasons. This changes the behavior of how authorities (when acting as clients) deal with nodes that have been listed by nickname. * I tried not to artificially increase the size of the diff here by moving functions around. As a result, some functions that now operate on nodes are now in the wrong file -- they should get moved to nodelist.c once this refactoring settles down. This moving should happen as part of a patch that moves functions AND NOTHING ELSE. * Some old code is now left around inside #if 0/1 blocks, and should get removed once I've verified that I don't want it sitting around to see how we used to do things. There are still some unimplemented functions: these are flagged with "UNIMPLEMENTED_NODELIST()." I'll work on filling in the implementation here, piece by piece. I wish this patch could have been smaller, but there did not seem to be any piece of it that was independent from the rest. Moving flags forces many functions that once returned routerinfo_t * to return node_t *, which forces their friends to change, and so on.
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#include "nodelist.h"
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#include "policies.h"
#include "router.h"
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#include "routerparse.h"
#include "geoip.h"
#include "ht.h"
/** Policy that addresses for incoming SOCKS connections must match. */
static smartlist_t *socks_policy = NULL;
/** Policy that addresses for incoming directory connections must match. */
static smartlist_t *dir_policy = NULL;
/** Policy that addresses for incoming router descriptors must match in order
* to be published by us. */
static smartlist_t *authdir_reject_policy = NULL;
/** Policy that addresses for incoming router descriptors must match in order
* to be marked as valid in our networkstatus. */
static smartlist_t *authdir_invalid_policy = NULL;
/** Policy that addresses for incoming router descriptors must <b>not</b>
* match in order to not be marked as BadExit. */
static smartlist_t *authdir_badexit_policy = NULL;
/** Parsed addr_policy_t describing which addresses we believe we can start
* circuits at. */
static smartlist_t *reachable_or_addr_policy = NULL;
/** Parsed addr_policy_t describing which addresses we believe we can connect
* to directories at. */
static smartlist_t *reachable_dir_addr_policy = NULL;
/** Element of an exit policy summary */
typedef struct policy_summary_item_t {
uint16_t prt_min; /**< Lowest port number to accept/reject. */
uint16_t prt_max; /**< Highest port number to accept/reject. */
uint64_t reject_count; /**< Number of IP-Addresses that are rejected to
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this port range. */
unsigned int accepted:1; /** Has this port already been accepted */
} policy_summary_item_t;
/** Private networks. This list is used in two places, once to expand the
* "private" keyword when parsing our own exit policy, secondly to ignore
* just such networks when building exit policy summaries. It is important
* that all authorities agree on that list when creating summaries, so don't
* just change this without a proper migration plan and a proposal and stuff.
*/
static const char *private_nets[] = {
"0.0.0.0/8", "169.254.0.0/16",
"127.0.0.0/8", "192.168.0.0/16", "10.0.0.0/8", "172.16.0.0/12",
"[::]/8",
"[fc00::]/7", "[fe80::]/10", "[fec0::]/10", "[ff00::]/8", "[::]/127",
NULL
};
static int policies_parse_exit_policy_internal(
config_line_t *cfg,
smartlist_t **dest,
int ipv6_exit,
int rejectprivate,
const smartlist_t *configured_addresses,
int reject_interface_addresses,
int reject_configured_port_addresses,
int add_default_policy);
/** Replace all "private" entries in *<b>policy</b> with their expanded
* equivalents. */
void
policy_expand_private(smartlist_t **policy)
{
uint16_t port_min, port_max;
int i;
smartlist_t *tmp;
if (!*policy) /*XXXX disallow NULL policies? */
return;
tmp = smartlist_new();
SMARTLIST_FOREACH_BEGIN(*policy, addr_policy_t *, p) {
if (! p->is_private) {
smartlist_add(tmp, p);
continue;
}
for (i = 0; private_nets[i]; ++i) {
addr_policy_t newpolicy;
memcpy(&newpolicy, p, sizeof(addr_policy_t));
newpolicy.is_private = 0;
newpolicy.is_canonical = 0;
if (tor_addr_parse_mask_ports(private_nets[i], 0,
&newpolicy.addr,
&newpolicy.maskbits, &port_min, &port_max)<0) {
tor_assert(0);
}
smartlist_add(tmp, addr_policy_get_canonical_entry(&newpolicy));
}
addr_policy_free(p);
} SMARTLIST_FOREACH_END(p);
smartlist_free(*policy);
*policy = tmp;
}
/** Expand each of the AF_UNSPEC elements in *<b>policy</b> (which indicate
* protocol-neutral wildcards) into a pair of wildcard elements: one IPv4-
* specific and one IPv6-specific. */
void
policy_expand_unspec(smartlist_t **policy)
{
smartlist_t *tmp;
if (!*policy)
return;
tmp = smartlist_new();
SMARTLIST_FOREACH_BEGIN(*policy, addr_policy_t *, p) {
sa_family_t family = tor_addr_family(&p->addr);
if (family == AF_INET6 || family == AF_INET || p->is_private) {
smartlist_add(tmp, p);
} else if (family == AF_UNSPEC) {
addr_policy_t newpolicy_ipv4;
addr_policy_t newpolicy_ipv6;
memcpy(&newpolicy_ipv4, p, sizeof(addr_policy_t));
memcpy(&newpolicy_ipv6, p, sizeof(addr_policy_t));
newpolicy_ipv4.is_canonical = 0;
newpolicy_ipv6.is_canonical = 0;
if (p->maskbits != 0) {
log_warn(LD_BUG, "AF_UNSPEC policy with maskbits==%d", p->maskbits);
newpolicy_ipv4.maskbits = 0;
newpolicy_ipv6.maskbits = 0;
}
tor_addr_from_ipv4h(&newpolicy_ipv4.addr, 0);
tor_addr_from_ipv6_bytes(&newpolicy_ipv6.addr,
"\0\0\0\0\0\0\0\0\0\0\0\0\0\0\0\0");
smartlist_add(tmp, addr_policy_get_canonical_entry(&newpolicy_ipv4));
smartlist_add(tmp, addr_policy_get_canonical_entry(&newpolicy_ipv6));
addr_policy_free(p);
} else {
log_warn(LD_BUG, "Funny-looking address policy with family %d", family);
smartlist_add(tmp, p);
}
} SMARTLIST_FOREACH_END(p);
smartlist_free(*policy);
*policy = tmp;
}
/**
* Given a linked list of config lines containing "accept[6]" and "reject[6]"
* tokens, parse them and append the result to <b>dest</b>. Return -1
* if any tokens are malformed (and don't append any), else return 0.
*
* If <b>assume_action</b> is nonnegative, then insert its action
* (ADDR_POLICY_ACCEPT or ADDR_POLICY_REJECT) for items that specify no
* action.
*/
static int
parse_addr_policy(config_line_t *cfg, smartlist_t **dest,
int assume_action)
{
smartlist_t *result;
smartlist_t *entries;
addr_policy_t *item;
int malformed_list;
int r = 0;
if (!cfg)
return 0;
result = smartlist_new();
entries = smartlist_new();
for (; cfg; cfg = cfg->next) {
smartlist_split_string(entries, cfg->value, ",",
SPLIT_SKIP_SPACE|SPLIT_IGNORE_BLANK, 0);
SMARTLIST_FOREACH_BEGIN(entries, const char *, ent) {
log_debug(LD_CONFIG,"Adding new entry '%s'",ent);
malformed_list = 0;
item = router_parse_addr_policy_item_from_string(ent, assume_action,
&malformed_list);
if (item) {
smartlist_add(result, item);
} else if (malformed_list) {
/* the error is so severe the entire list should be discarded */
log_warn(LD_CONFIG, "Malformed policy '%s'. Discarding entire policy "
"list.", ent);
r = -1;
} else {
/* the error is minor: don't add the item, but keep processing the
* rest of the policies in the list */
log_debug(LD_CONFIG, "Ignored policy '%s' due to non-fatal error. "
"The remainder of the policy list will be used.",
ent);
}
} SMARTLIST_FOREACH_END(ent);
SMARTLIST_FOREACH(entries, char *, ent, tor_free(ent));
smartlist_clear(entries);
}
smartlist_free(entries);
if (r == -1) {
addr_policy_list_free(result);
} else {
policy_expand_private(&result);
policy_expand_unspec(&result);
if (*dest) {
smartlist_add_all(*dest, result);
smartlist_free(result);
} else {
*dest = result;
}
}
return r;
}
/** Helper: parse the Reachable(Dir|OR)?Addresses fields into
* reachable_(or|dir)_addr_policy. The options should already have
* been validated by validate_addr_policies.
*/
static int
parse_reachable_addresses(void)
{
const or_options_t *options = get_options();
int ret = 0;
if (options->ReachableDirAddresses &&
options->ReachableORAddresses &&
options->ReachableAddresses) {
log_warn(LD_CONFIG,
"Both ReachableDirAddresses and ReachableORAddresses are set. "
"ReachableAddresses setting will be ignored.");
}
addr_policy_list_free(reachable_or_addr_policy);
reachable_or_addr_policy = NULL;
if (!options->ReachableORAddresses && options->ReachableAddresses)
log_info(LD_CONFIG,
"Using ReachableAddresses as ReachableORAddresses.");
if (parse_addr_policy(options->ReachableORAddresses ?
options->ReachableORAddresses :
options->ReachableAddresses,
&reachable_or_addr_policy, ADDR_POLICY_ACCEPT)) {
log_warn(LD_CONFIG,
"Error parsing Reachable%sAddresses entry; ignoring.",
options->ReachableORAddresses ? "OR" : "");
ret = -1;
}
addr_policy_list_free(reachable_dir_addr_policy);
reachable_dir_addr_policy = NULL;
if (!options->ReachableDirAddresses && options->ReachableAddresses)
log_info(LD_CONFIG,
"Using ReachableAddresses as ReachableDirAddresses");
if (parse_addr_policy(options->ReachableDirAddresses ?
options->ReachableDirAddresses :
options->ReachableAddresses,
&reachable_dir_addr_policy, ADDR_POLICY_ACCEPT)) {
if (options->ReachableDirAddresses)
log_warn(LD_CONFIG,
"Error parsing ReachableDirAddresses entry; ignoring.");
ret = -1;
}
/* We ignore ReachableAddresses for relays */
if (!server_mode(options)) {
if ((reachable_or_addr_policy
&& policy_is_reject_star(reachable_or_addr_policy, AF_UNSPEC))
|| (reachable_dir_addr_policy
&& policy_is_reject_star(reachable_dir_addr_policy, AF_UNSPEC))) {
log_warn(LD_CONFIG, "Tor cannot connect to the Internet if "
"ReachableAddresses, ReachableORAddresses, or "
"ReachableDirAddresses reject all addresses. Please accept "
"some addresses in these options.");
} else if (options->ClientUseIPv4 == 1
&& ((reachable_or_addr_policy
&& policy_is_reject_star(reachable_or_addr_policy, AF_INET))
|| (reachable_dir_addr_policy
&& policy_is_reject_star(reachable_dir_addr_policy, AF_INET)))) {
log_warn(LD_CONFIG, "You have set ClientUseIPv4 1, but "
"ReachableAddresses, ReachableORAddresses, or "
"ReachableDirAddresses reject all IPv4 addresses. "
"Tor will not connect using IPv4.");
} else if (fascist_firewall_use_ipv6(options)
&& ((reachable_or_addr_policy
&& policy_is_reject_star(reachable_or_addr_policy, AF_INET6))
|| (reachable_dir_addr_policy
&& policy_is_reject_star(reachable_dir_addr_policy, AF_INET6)))) {
log_warn(LD_CONFIG, "You have configured tor to use IPv6 "
"(ClientUseIPv6 1 or UseBridges 1), but "
"ReachableAddresses, ReachableORAddresses, or "
"ReachableDirAddresses reject all IPv6 addresses. "
"Tor will not connect using IPv6.");
}
}
return ret;
}
/* Return true iff ClientUseIPv4 0 or ClientUseIPv6 0 might block any OR or Dir
* address:port combination. */
static int
firewall_is_fascist_impl(void)
{
const or_options_t *options = get_options();
/* Assume every non-bridge relay has an IPv4 address.
* Clients which use bridges may only know the IPv6 address of their
* bridge. */
return (options->ClientUseIPv4 == 0
|| (!fascist_firewall_use_ipv6(options)
&& options->UseBridges == 1));
}
/** Return true iff the firewall options, including ClientUseIPv4 0 and
* ClientUseIPv6 0, might block any OR address:port combination.
* Address preferences may still change which address is selected even if
* this function returns false.
*/
int
firewall_is_fascist_or(void)
{
return (reachable_or_addr_policy != NULL || firewall_is_fascist_impl());
}
/** Return true iff the firewall options, including ClientUseIPv4 0 and
* ClientUseIPv6 0, might block any Dir address:port combination.
* Address preferences may still change which address is selected even if
* this function returns false.
*/
int
firewall_is_fascist_dir(void)
{
return (reachable_dir_addr_policy != NULL || firewall_is_fascist_impl());
}
/** Return true iff <b>policy</b> (possibly NULL) will allow a
* connection to <b>addr</b>:<b>port</b>.
*/
static int
addr_policy_permits_tor_addr(const tor_addr_t *addr, uint16_t port,
smartlist_t *policy)
{
addr_policy_result_t p;
p = compare_tor_addr_to_addr_policy(addr, port, policy);
switch (p) {
case ADDR_POLICY_PROBABLY_ACCEPTED:
case ADDR_POLICY_ACCEPTED:
return 1;
case ADDR_POLICY_PROBABLY_REJECTED:
case ADDR_POLICY_REJECTED:
return 0;
default:
log_warn(LD_BUG, "Unexpected result: %d", (int)p);
return 0;
}
}
/** Return true iff <b> policy</b> (possibly NULL) will allow a connection to
* <b>addr</b>:<b>port</b>. <b>addr</b> is an IPv4 address given in host
* order. */
/* XXXX deprecate when possible. */
static int
addr_policy_permits_address(uint32_t addr, uint16_t port,
smartlist_t *policy)
{
tor_addr_t a;
tor_addr_from_ipv4h(&a, addr);
return addr_policy_permits_tor_addr(&a, port, policy);
}
/** Return true iff we think our firewall will let us make a connection to
* addr:port.
*
* If we are configured as a server, ignore any address family preference and
* just use IPv4.
* Otherwise:
* - return false for all IPv4 addresses:
* - if ClientUseIPv4 is 0, or
* if pref_only and pref_ipv6 are both true;
* - return false for all IPv6 addresses:
* - if fascist_firewall_use_ipv6() is 0, or
* - if pref_only is true and pref_ipv6 is false.
*
* Return false if addr is NULL or tor_addr_is_null(), or if port is 0. */
STATIC int
fascist_firewall_allows_address(const tor_addr_t *addr,
uint16_t port,
smartlist_t *firewall_policy,
int pref_only, int pref_ipv6)
{
const or_options_t *options = get_options();
if (!addr || tor_addr_is_null(addr) || !port) {
return 0;
}
if (!server_mode(options)) {
if (tor_addr_family(addr) == AF_INET &&
(!options->ClientUseIPv4 || (pref_only && pref_ipv6)))
return 0;
}
if (tor_addr_family(addr) == AF_INET6 &&
(!fascist_firewall_use_ipv6(options) || (pref_only && !pref_ipv6)))
return 0;
return addr_policy_permits_tor_addr(addr, port,
firewall_policy);
}
/** Is this client configured to use IPv6?
*/
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int
fascist_firewall_use_ipv6(const or_options_t *options)
{
/* Clients use IPv6 if it's set, or they use bridges, or they don't use
* IPv4 */
return (options->ClientUseIPv6 == 1 || options->UseBridges == 1
|| options->ClientUseIPv4 == 0);
}
/** Do we prefer to connect to IPv6, ignoring ClientPreferIPv6ORPort and
* ClientPreferIPv6DirPort?
* If we're unsure, return -1, otherwise, return 1 for IPv6 and 0 for IPv4.
*/
static int
fascist_firewall_prefer_ipv6_impl(const or_options_t *options)
{
/*
Cheap implementation of config options ClientUseIPv4 & ClientUseIPv6 --
If we're a server or IPv6 is disabled, use IPv4.
If IPv4 is disabled, use IPv6.
*/
if (server_mode(options) || !fascist_firewall_use_ipv6(options)) {
return 0;
}
if (!options->ClientUseIPv4) {
return 1;
}
return -1;
}
/** Do we prefer to connect to IPv6 ORPorts?
*/
int
fascist_firewall_prefer_ipv6_orport(const or_options_t *options)
{
/* node->ipv6_preferred is set from fascist_firewall_prefer_ipv6_orport()
* each time the consensus is loaded.
* If our preferences change, we will only reset ipv6_preferred on the node
* when the next consensus is loaded. But the consensus is realoded when the
* configuration changes after a HUP. So as long as the result of this
* function only depends on Tor's options, everything should work ok.
*/
int pref_ipv6 = fascist_firewall_prefer_ipv6_impl(options);
if (pref_ipv6 >= 0) {
return pref_ipv6;
}
/* We can use both IPv4 and IPv6 - which do we prefer? */
if (options->ClientPreferIPv6ORPort == 1) {
return 1;
}
return 0;
}
/** Do we prefer to connect to IPv6 DirPorts?
*/
int
fascist_firewall_prefer_ipv6_dirport(const or_options_t *options)
{
int pref_ipv6 = fascist_firewall_prefer_ipv6_impl(options);
if (pref_ipv6 >= 0) {
return pref_ipv6;
}
/* We can use both IPv4 and IPv6 - which do we prefer? */
if (options->ClientPreferIPv6DirPort == 1) {
return 1;
}
return 0;
}
/** Return true iff we think our firewall will let us make a connection to
* addr:port. Uses ReachableORAddresses or ReachableDirAddresses based on
* fw_connection.
* If pref_only, return false if addr is not in the client's preferred address
* family.
*/
Initial conversion to use node_t throughout our codebase. A node_t is an abstraction over routerstatus_t, routerinfo_t, and microdesc_t. It should try to present a consistent interface to all of them. There should be a node_t for a server whenever there is * A routerinfo_t for it in the routerlist * A routerstatus_t in the current_consensus. (note that a microdesc_t alone isn't enough to make a node_t exist, since microdescriptors aren't usable on their own.) There are three ways to get a node_t right now: looking it up by ID, looking it up by nickname, and iterating over the whole list of microdescriptors. All (or nearly all) functions that are supposed to return "a router" -- especially those used in building connections and circuits -- should return a node_t, not a routerinfo_t or a routerstatus_t. A node_t should hold all the *mutable* flags about a node. This patch moves the is_foo flags from routerinfo_t into node_t. The flags in routerstatus_t remain, but they get set from the consensus and should not change. Some other highlights of this patch are: * Looking up routerinfo and routerstatus by nickname is now unified and based on the "look up a node by nickname" function. This tries to look only at the values from current consensus, and not get confused by the routerinfo_t->is_named flag, which could get set for other weird reasons. This changes the behavior of how authorities (when acting as clients) deal with nodes that have been listed by nickname. * I tried not to artificially increase the size of the diff here by moving functions around. As a result, some functions that now operate on nodes are now in the wrong file -- they should get moved to nodelist.c once this refactoring settles down. This moving should happen as part of a patch that moves functions AND NOTHING ELSE. * Some old code is now left around inside #if 0/1 blocks, and should get removed once I've verified that I don't want it sitting around to see how we used to do things. There are still some unimplemented functions: these are flagged with "UNIMPLEMENTED_NODELIST()." I'll work on filling in the implementation here, piece by piece. I wish this patch could have been smaller, but there did not seem to be any piece of it that was independent from the rest. Moving flags forces many functions that once returned routerinfo_t * to return node_t *, which forces their friends to change, and so on.
2010-09-29 21:00:41 +02:00
int
fascist_firewall_allows_address_addr(const tor_addr_t *addr, uint16_t port,
firewall_connection_t fw_connection,
int pref_only)
{
const or_options_t *options = get_options();
if (fw_connection == FIREWALL_OR_CONNECTION) {
return fascist_firewall_allows_address(addr, port,
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reachable_or_addr_policy,
pref_only,
fascist_firewall_prefer_ipv6_orport(options));
} else if (fw_connection == FIREWALL_DIR_CONNECTION) {
return fascist_firewall_allows_address(addr, port,
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reachable_dir_addr_policy,
pref_only,
fascist_firewall_prefer_ipv6_dirport(options));
Initial conversion to use node_t throughout our codebase. A node_t is an abstraction over routerstatus_t, routerinfo_t, and microdesc_t. It should try to present a consistent interface to all of them. There should be a node_t for a server whenever there is * A routerinfo_t for it in the routerlist * A routerstatus_t in the current_consensus. (note that a microdesc_t alone isn't enough to make a node_t exist, since microdescriptors aren't usable on their own.) There are three ways to get a node_t right now: looking it up by ID, looking it up by nickname, and iterating over the whole list of microdescriptors. All (or nearly all) functions that are supposed to return "a router" -- especially those used in building connections and circuits -- should return a node_t, not a routerinfo_t or a routerstatus_t. A node_t should hold all the *mutable* flags about a node. This patch moves the is_foo flags from routerinfo_t into node_t. The flags in routerstatus_t remain, but they get set from the consensus and should not change. Some other highlights of this patch are: * Looking up routerinfo and routerstatus by nickname is now unified and based on the "look up a node by nickname" function. This tries to look only at the values from current consensus, and not get confused by the routerinfo_t->is_named flag, which could get set for other weird reasons. This changes the behavior of how authorities (when acting as clients) deal with nodes that have been listed by nickname. * I tried not to artificially increase the size of the diff here by moving functions around. As a result, some functions that now operate on nodes are now in the wrong file -- they should get moved to nodelist.c once this refactoring settles down. This moving should happen as part of a patch that moves functions AND NOTHING ELSE. * Some old code is now left around inside #if 0/1 blocks, and should get removed once I've verified that I don't want it sitting around to see how we used to do things. There are still some unimplemented functions: these are flagged with "UNIMPLEMENTED_NODELIST()." I'll work on filling in the implementation here, piece by piece. I wish this patch could have been smaller, but there did not seem to be any piece of it that was independent from the rest. Moving flags forces many functions that once returned routerinfo_t * to return node_t *, which forces their friends to change, and so on.
2010-09-29 21:00:41 +02:00
} else {
log_warn(LD_BUG, "Bad firewall_connection_t value %d.",
fw_connection);
return 0;
}
}
/** Return true iff we think our firewall will let us make a connection to
* addr:port (ap). Uses ReachableORAddresses or ReachableDirAddresses based on
* fw_connection.
* If pref_only, return false if addr is not in the client's preferred address
* family.
*/
int
fascist_firewall_allows_address_ap(const tor_addr_port_t *ap,
firewall_connection_t fw_connection,
int pref_only)
{
tor_assert(ap);
return fascist_firewall_allows_address_addr(&ap->addr, ap->port,
fw_connection, pref_only);
}
/* Return true iff we think our firewall will let us make a connection to
* ipv4h_or_addr:ipv4_or_port. ipv4h_or_addr is interpreted in host order.
* Uses ReachableORAddresses or ReachableDirAddresses based on
* fw_connection.
* If pref_only, return false if addr is not in the client's preferred address
* family. */
int
fascist_firewall_allows_address_ipv4h(uint32_t ipv4h_or_addr,
uint16_t ipv4_or_port,
firewall_connection_t fw_connection,
int pref_only)
{
tor_addr_t ipv4_or_addr;
tor_addr_from_ipv4h(&ipv4_or_addr, ipv4h_or_addr);
return fascist_firewall_allows_address_addr(&ipv4_or_addr, ipv4_or_port,
fw_connection, pref_only);
}
/** Return true iff we think our firewall will let us make a connection to
* ipv4h_addr/ipv6_addr. Uses ipv4_orport/ipv6_orport/ReachableORAddresses or
* ipv4_dirport/ipv6_dirport/ReachableDirAddresses based on IPv4/IPv6 and
* <b>fw_connection</b>.
* If pref_only, return false if addr is not in the client's preferred address
* family. */
static int
fascist_firewall_allows_base(uint32_t ipv4h_addr, uint16_t ipv4_orport,
uint16_t ipv4_dirport,
const tor_addr_t *ipv6_addr, uint16_t ipv6_orport,
uint16_t ipv6_dirport,
firewall_connection_t fw_connection,
int pref_only)
{
if (fascist_firewall_allows_address_ipv4h(ipv4h_addr,
(fw_connection == FIREWALL_OR_CONNECTION
? ipv4_orport
: ipv4_dirport),
fw_connection,
pref_only)) {
Initial conversion to use node_t throughout our codebase. A node_t is an abstraction over routerstatus_t, routerinfo_t, and microdesc_t. It should try to present a consistent interface to all of them. There should be a node_t for a server whenever there is * A routerinfo_t for it in the routerlist * A routerstatus_t in the current_consensus. (note that a microdesc_t alone isn't enough to make a node_t exist, since microdescriptors aren't usable on their own.) There are three ways to get a node_t right now: looking it up by ID, looking it up by nickname, and iterating over the whole list of microdescriptors. All (or nearly all) functions that are supposed to return "a router" -- especially those used in building connections and circuits -- should return a node_t, not a routerinfo_t or a routerstatus_t. A node_t should hold all the *mutable* flags about a node. This patch moves the is_foo flags from routerinfo_t into node_t. The flags in routerstatus_t remain, but they get set from the consensus and should not change. Some other highlights of this patch are: * Looking up routerinfo and routerstatus by nickname is now unified and based on the "look up a node by nickname" function. This tries to look only at the values from current consensus, and not get confused by the routerinfo_t->is_named flag, which could get set for other weird reasons. This changes the behavior of how authorities (when acting as clients) deal with nodes that have been listed by nickname. * I tried not to artificially increase the size of the diff here by moving functions around. As a result, some functions that now operate on nodes are now in the wrong file -- they should get moved to nodelist.c once this refactoring settles down. This moving should happen as part of a patch that moves functions AND NOTHING ELSE. * Some old code is now left around inside #if 0/1 blocks, and should get removed once I've verified that I don't want it sitting around to see how we used to do things. There are still some unimplemented functions: these are flagged with "UNIMPLEMENTED_NODELIST()." I'll work on filling in the implementation here, piece by piece. I wish this patch could have been smaller, but there did not seem to be any piece of it that was independent from the rest. Moving flags forces many functions that once returned routerinfo_t * to return node_t *, which forces their friends to change, and so on.
2010-09-29 21:00:41 +02:00
return 1;
}
if (fascist_firewall_allows_address_addr(ipv6_addr,
(fw_connection == FIREWALL_OR_CONNECTION
? ipv6_orport
: ipv6_dirport),
fw_connection,
pref_only)) {
return 1;
}
return 0;
}
/** Like fascist_firewall_allows_ri, but doesn't consult the node. */
static int
fascist_firewall_allows_ri_impl(const routerinfo_t *ri,
firewall_connection_t fw_connection,
int pref_only)
{
if (!ri) {
return 0;
}
/* Assume IPv4 and IPv6 DirPorts are the same */
return fascist_firewall_allows_base(ri->addr, ri->or_port, ri->dir_port,
&ri->ipv6_addr, ri->ipv6_orport,
ri->dir_port, fw_connection, pref_only);
}
/** Like fascist_firewall_allows_rs, but doesn't consult the node. */
static int
fascist_firewall_allows_rs_impl(const routerstatus_t *rs,
firewall_connection_t fw_connection,
int pref_only)
{
if (!rs) {
return 0;
}
/* Assume IPv4 and IPv6 DirPorts are the same */
return fascist_firewall_allows_base(rs->addr, rs->or_port, rs->dir_port,
&rs->ipv6_addr, rs->ipv6_orport,
rs->dir_port, fw_connection, pref_only);
Initial conversion to use node_t throughout our codebase. A node_t is an abstraction over routerstatus_t, routerinfo_t, and microdesc_t. It should try to present a consistent interface to all of them. There should be a node_t for a server whenever there is * A routerinfo_t for it in the routerlist * A routerstatus_t in the current_consensus. (note that a microdesc_t alone isn't enough to make a node_t exist, since microdescriptors aren't usable on their own.) There are three ways to get a node_t right now: looking it up by ID, looking it up by nickname, and iterating over the whole list of microdescriptors. All (or nearly all) functions that are supposed to return "a router" -- especially those used in building connections and circuits -- should return a node_t, not a routerinfo_t or a routerstatus_t. A node_t should hold all the *mutable* flags about a node. This patch moves the is_foo flags from routerinfo_t into node_t. The flags in routerstatus_t remain, but they get set from the consensus and should not change. Some other highlights of this patch are: * Looking up routerinfo and routerstatus by nickname is now unified and based on the "look up a node by nickname" function. This tries to look only at the values from current consensus, and not get confused by the routerinfo_t->is_named flag, which could get set for other weird reasons. This changes the behavior of how authorities (when acting as clients) deal with nodes that have been listed by nickname. * I tried not to artificially increase the size of the diff here by moving functions around. As a result, some functions that now operate on nodes are now in the wrong file -- they should get moved to nodelist.c once this refactoring settles down. This moving should happen as part of a patch that moves functions AND NOTHING ELSE. * Some old code is now left around inside #if 0/1 blocks, and should get removed once I've verified that I don't want it sitting around to see how we used to do things. There are still some unimplemented functions: these are flagged with "UNIMPLEMENTED_NODELIST()." I'll work on filling in the implementation here, piece by piece. I wish this patch could have been smaller, but there did not seem to be any piece of it that was independent from the rest. Moving flags forces many functions that once returned routerinfo_t * to return node_t *, which forces their friends to change, and so on.
2010-09-29 21:00:41 +02:00
}
/** Return true iff we think our firewall will let us make a connection to
* <b>rs</b> on either its IPv4 or IPv6 address. Uses
* or_port/ipv6_orport/ReachableORAddresses or dir_port/ReachableDirAddresses
* based on IPv4/IPv6 and <b>fw_connection</b>.
* If pref_only, return false if addr is not in the client's preferred address
* family.
* Consults the corresponding node if the addresses in rs are not permitted. */
int
fascist_firewall_allows_rs(const routerstatus_t *rs,
firewall_connection_t fw_connection, int pref_only)
{
if (!rs) {
return 0;
}
/* Assume IPv4 and IPv6 DirPorts are the same */
if (fascist_firewall_allows_rs_impl(rs, fw_connection, pref_only)) {
return 1;
Initial conversion to use node_t throughout our codebase. A node_t is an abstraction over routerstatus_t, routerinfo_t, and microdesc_t. It should try to present a consistent interface to all of them. There should be a node_t for a server whenever there is * A routerinfo_t for it in the routerlist * A routerstatus_t in the current_consensus. (note that a microdesc_t alone isn't enough to make a node_t exist, since microdescriptors aren't usable on their own.) There are three ways to get a node_t right now: looking it up by ID, looking it up by nickname, and iterating over the whole list of microdescriptors. All (or nearly all) functions that are supposed to return "a router" -- especially those used in building connections and circuits -- should return a node_t, not a routerinfo_t or a routerstatus_t. A node_t should hold all the *mutable* flags about a node. This patch moves the is_foo flags from routerinfo_t into node_t. The flags in routerstatus_t remain, but they get set from the consensus and should not change. Some other highlights of this patch are: * Looking up routerinfo and routerstatus by nickname is now unified and based on the "look up a node by nickname" function. This tries to look only at the values from current consensus, and not get confused by the routerinfo_t->is_named flag, which could get set for other weird reasons. This changes the behavior of how authorities (when acting as clients) deal with nodes that have been listed by nickname. * I tried not to artificially increase the size of the diff here by moving functions around. As a result, some functions that now operate on nodes are now in the wrong file -- they should get moved to nodelist.c once this refactoring settles down. This moving should happen as part of a patch that moves functions AND NOTHING ELSE. * Some old code is now left around inside #if 0/1 blocks, and should get removed once I've verified that I don't want it sitting around to see how we used to do things. There are still some unimplemented functions: these are flagged with "UNIMPLEMENTED_NODELIST()." I'll work on filling in the implementation here, piece by piece. I wish this patch could have been smaller, but there did not seem to be any piece of it that was independent from the rest. Moving flags forces many functions that once returned routerinfo_t * to return node_t *, which forces their friends to change, and so on.
2010-09-29 21:00:41 +02:00
} else {
const node_t *node = node_get_by_id(rs->identity_digest);
return fascist_firewall_allows_node(node, fw_connection, pref_only);
}
}
/** Like fascist_firewall_allows_md, but doesn't consult the node. */
static int
fascist_firewall_allows_md_impl(const microdesc_t *md,
firewall_connection_t fw_connection,
int pref_only)
{
if (!md) {
return 0;
}
/* Can't check dirport, it doesn't have one */
if (fw_connection == FIREWALL_DIR_CONNECTION) {
return 0;
}
/* Also can't check IPv4, doesn't have that either */
return fascist_firewall_allows_address_addr(&md->ipv6_addr, md->ipv6_orport,
fw_connection, pref_only);
}
/** Return true iff we think our firewall will let us make a connection to
* <b>node</b>:
* - if <b>preferred</b> is true, on its preferred address,
* - if not, on either its IPv4 or IPv6 address.
* Uses or_port/ipv6_orport/ReachableORAddresses or
* dir_port/ReachableDirAddresses based on IPv4/IPv6 and <b>fw_connection</b>.
* If pref_only, return false if addr is not in the client's preferred address
* family. */
int
fascist_firewall_allows_node(const node_t *node,
firewall_connection_t fw_connection,
int pref_only)
{
if (!node) {
return 0;
}
node_assert_ok(node);
/* Sometimes, the rs is missing the IPv6 address info, and we need to go
* all the way to the md */
if (node->ri && fascist_firewall_allows_ri_impl(node->ri, fw_connection,
pref_only)) {
return 1;
} else if (node->rs && fascist_firewall_allows_rs_impl(node->rs,
fw_connection,
pref_only)) {
return 1;
} else if (node->md && fascist_firewall_allows_md_impl(node->md,
fw_connection,
pref_only)) {
return 1;
} else {
/* If we know nothing, assume it's unreachable, we'll never get an address
* to connect to. */
return 0;
}
}
/** Return true iff we think our firewall will let us make a connection to
* <b>ds</b> on either its IPv4 or IPv6 address. Uses ReachableORAddresses or
* ReachableDirAddresses based on <b>fw_connection</b> (some directory
* connections are tunneled over ORPorts).
* If pref_only, return false if addr is not in the client's preferred address
* family. */
int
fascist_firewall_allows_dir_server(const dir_server_t *ds,
firewall_connection_t fw_connection,
int pref_only)
{
if (!ds) {
return 0;
}
/* A dir_server_t always has a fake_status. As long as it has the same
* addresses/ports in both fake_status and dir_server_t, this works fine.
* (See #17867.)
* This function relies on fascist_firewall_allows_rs looking up the node on
* failure, because it will get the latest info for the relay. */
return fascist_firewall_allows_rs(&ds->fake_status, fw_connection,
pref_only);
}
/** If a and b are both valid and allowed by fw_connection,
* choose one based on want_a and return it.
* Otherwise, return whichever is allowed.
* Otherwise, return NULL.
* If pref_only, only return an address if it's in the client's preferred
* address family. */
static const tor_addr_port_t *
fascist_firewall_choose_address_impl(const tor_addr_port_t *a,
const tor_addr_port_t *b,
int want_a,
firewall_connection_t fw_connection,
int pref_only)
{
const tor_addr_port_t *use_a = NULL;
const tor_addr_port_t *use_b = NULL;
if (fascist_firewall_allows_address_ap(a, fw_connection, pref_only)) {
use_a = a;
}
if (fascist_firewall_allows_address_ap(b, fw_connection, pref_only)) {
use_b = b;
}
/* If both are allowed */
if (use_a && use_b) {
/* Choose a if we want it */
return (want_a ? use_a : use_b);
} else {
/* Choose a if we have it */
return (use_a ? use_a : use_b);
}
}
/** If a and b are both valid and preferred by fw_connection,
* choose one based on want_a and return it.
* Otherwise, return whichever is preferred.
* If neither are preferred, and pref_only is false:
* - If a and b are both allowed by fw_connection,
* choose one based on want_a and return it.
* - Otherwise, return whichever is preferred.
* Otherwise, return NULL. */
const tor_addr_port_t *
fascist_firewall_choose_address(const tor_addr_port_t *a,
const tor_addr_port_t *b,
int want_a,
firewall_connection_t fw_connection,
int pref_only)
{
const tor_addr_port_t *pref = fascist_firewall_choose_address_impl(
a, b, want_a,
fw_connection,
1);
if (pref_only || pref) {
/* If there is a preferred address, use it. If we can only use preferred
* addresses, and neither address is preferred, pref will be NULL, and we
* want to return NULL, so return it. */
return pref;
} else {
/* If there's no preferred address, and we can return addresses that are
* not preferred, use an address that's allowed */
return fascist_firewall_choose_address_impl(a, b, want_a, fw_connection,
0);
}
}
/** Copy an address and port into <b>ap</b> that we think our firewall will
* let us connect to. Uses ipv4_addr/ipv6_addr and
* ipv4_orport/ipv6_orport/ReachableORAddresses or
* ipv4_dirport/ipv6_dirport/ReachableDirAddresses based on IPv4/IPv6 and
* <b>fw_connection</b>.
* If pref_only, only choose preferred addresses. In either case, choose
* a preferred address before an address that's not preferred.
* If neither address is chosen, return 0, else return 1. */
static int
fascist_firewall_choose_address_base(const tor_addr_t *ipv4_addr,
uint16_t ipv4_orport,
uint16_t ipv4_dirport,
const tor_addr_t *ipv6_addr,
uint16_t ipv6_orport,
uint16_t ipv6_dirport,
firewall_connection_t fw_connection,
int pref_only,
tor_addr_port_t* ap)
{
const tor_addr_port_t *result = NULL;
/* This argument is ignored as long as the address pair is IPv4/IPv6,
* because we always have a preference in a client.
* For bridge clients, this selects the preferred address, which was
* previously IPv6 (if a bridge has both), so we keep that behaviour. */
const int bridge_client_prefer_ipv4 = 0;
tor_assert(ipv6_addr);
tor_assert(ap);
tor_addr_port_t ipv4_ap;
tor_addr_copy(&ipv4_ap.addr, ipv4_addr);
ipv4_ap.port = (fw_connection == FIREWALL_OR_CONNECTION
? ipv4_orport
: ipv4_dirport);
tor_addr_port_t ipv6_ap;
tor_addr_copy(&ipv6_ap.addr, ipv6_addr);
ipv6_ap.port = (fw_connection == FIREWALL_OR_CONNECTION
? ipv6_orport
: ipv6_dirport);
result = fascist_firewall_choose_address(&ipv4_ap, &ipv6_ap,
bridge_client_prefer_ipv4,
fw_connection, pref_only);
if (result) {
tor_addr_copy(&ap->addr, &result->addr);
ap->port = result->port;
return 1;
} else {
return 0;
}
}
/** Like fascist_firewall_choose_address_base, but takes a host-order IPv4
* address as the first parameter. */
static int
fascist_firewall_choose_address_ipv4h(uint32_t ipv4h_addr,
uint16_t ipv4_orport,
uint16_t ipv4_dirport,
const tor_addr_t *ipv6_addr,
uint16_t ipv6_orport,
uint16_t ipv6_dirport,
firewall_connection_t fw_connection,
int pref_only,
tor_addr_port_t* ap)
{
tor_addr_t ipv4_addr;
tor_addr_from_ipv4h(&ipv4_addr, ipv4h_addr);
return fascist_firewall_choose_address_base(&ipv4_addr, ipv4_orport,
ipv4_dirport, ipv6_addr,
ipv6_orport, ipv6_dirport,
fw_connection, pref_only, ap);
}
#define IPV6_OR_LOOKUP(r, identity_digest, ipv6_or_ap) \
STMT_BEGIN \
if (!(r)->ipv6_orport || tor_addr_is_null(&(r)->ipv6_addr)) { \
const node_t *node = node_get_by_id((identity_digest)); \
if (node) { \
node_get_pref_ipv6_orport(node, &(ipv6_or_ap)); \
} else { \
tor_addr_make_null(&(ipv6_or_ap).addr, AF_INET6); \
(ipv6_or_ap).port = 0; \
} \
} else { \
tor_addr_copy(&(ipv6_or_ap).addr, &(r)->ipv6_addr); \
(ipv6_or_ap).port = (r)->ipv6_orport; \
} \
STMT_END
/** Copy an address and port from <b>rs</b> into <b>ap</b> that we think our
* firewall will let us connect to. Uses ipv4h_addr/ipv6_addr and
* ipv4_orport/ipv6_orport/ReachableORAddresses or
* ipv4_dirport/ipv6_dirport/ReachableDirAddresses based on IPv4/IPv6 and
* <b>fw_connection</b>.
* If pref_only, only choose preferred addresses. In either case, choose
* a preferred address before an address that's not preferred.
* If neither address is chosen, return 0, else return 1.
* Consults the corresponding node if the addresses in rs are not valid. */
int
fascist_firewall_choose_address_rs(const routerstatus_t *rs,
firewall_connection_t fw_connection,
int pref_only, tor_addr_port_t* ap)
{
if (!rs) {
return 0;
}
tor_assert(ap);
/* Don't do the lookup if the IPv6 address/port in rs is OK.
* If it's OK, assume the dir_port is also OK. */
tor_addr_port_t ipv6_or_ap;
IPV6_OR_LOOKUP(rs, rs->identity_digest, ipv6_or_ap);
/* Assume IPv4 and IPv6 DirPorts are the same.
* Assume the IPv6 OR and Dir addresses are the same. */
return fascist_firewall_choose_address_ipv4h(rs->addr,
rs->or_port,
rs->dir_port,
&ipv6_or_ap.addr,
ipv6_or_ap.port,
rs->dir_port,
fw_connection,
pref_only,
ap);
}
/** Copy an address and port from <b>node</b> into <b>ap</b> that we think our
* firewall will let us connect to. Uses ipv4h_addr/ipv6_addr and
* ipv4_orport/ipv6_orport/ReachableORAddresses or
* ipv4_dirport/ipv6_dirport/ReachableDirAddresses based on IPv4/IPv6 and
* <b>fw_connection</b>.
* If pref_only, only choose preferred addresses. In either case, choose
* a preferred address before an address that's not preferred.
* If neither address is chosen, return 0, else return 1. */
int
fascist_firewall_choose_address_node(const node_t *node,
firewall_connection_t fw_connection,
int pref_only, tor_addr_port_t *ap)
{
if (!node) {
return 0;
}
node_assert_ok(node);
tor_addr_port_t ipv4_or_ap;
node_get_prim_orport(node, &ipv4_or_ap);
tor_addr_port_t ipv4_dir_ap;
node_get_prim_dirport(node, &ipv4_dir_ap);
tor_addr_port_t ipv6_or_ap;
node_get_pref_ipv6_orport(node, &ipv6_or_ap);
tor_addr_port_t ipv6_dir_ap;
node_get_pref_ipv6_dirport(node, &ipv6_dir_ap);
/* Assume the IPv6 OR and Dir addresses are the same. */
return fascist_firewall_choose_address_base(&ipv4_or_ap.addr,
ipv4_or_ap.port,
ipv4_dir_ap.port,
&ipv6_or_ap.addr,
ipv6_or_ap.port,
ipv6_dir_ap.port,
fw_connection,
pref_only,
ap);
}
/** Copy an address and port from <b>ds</b> into <b>ap</b> that we think our
* firewall will let us connect to. Uses ipv4h_addr/ipv6_addr and
* ipv4_orport/ipv6_orport/ReachableORAddresses or
* ipv4_dirport/ipv6_dirport/ReachableDirAddresses based on IPv4/IPv6 and
* <b>fw_connection</b>.
* If pref_only, only choose preferred addresses. In either case, choose
* a preferred address before an address that's not preferred.
* If neither address is chosen, return 0, else return 1. */
int
fascist_firewall_choose_address_dir_server(const dir_server_t *ds,
firewall_connection_t fw_connection,
int pref_only, tor_addr_port_t *ap)
{
if (!ds) {
return 0;
}
/* A dir_server_t always has a fake_status. As long as it has the same
* addresses/ports in both fake_status and dir_server_t, this works fine.
* (See #17867.)
* This function relies on fascist_firewall_choose_address_rs looking up the
* addresses from the node if it can, because that will get the latest info
* for the relay. */
return fascist_firewall_choose_address_rs(&ds->fake_status, fw_connection,
pref_only, ap);
}
/** Return 1 if <b>addr</b> is permitted to connect to our dir port,
* based on <b>dir_policy</b>. Else return 0.
*/
int
dir_policy_permits_address(const tor_addr_t *addr)
{
return addr_policy_permits_tor_addr(addr, 1, dir_policy);
}
/** Return 1 if <b>addr</b> is permitted to connect to our socks port,
* based on <b>socks_policy</b>. Else return 0.
*/
int
socks_policy_permits_address(const tor_addr_t *addr)
{
return addr_policy_permits_tor_addr(addr, 1, socks_policy);
}
/** Return true iff the address <b>addr</b> is in a country listed in the
* case-insensitive list of country codes <b>cc_list</b>. */
static int
addr_is_in_cc_list(uint32_t addr, const smartlist_t *cc_list)
{
country_t country;
const char *name;
2012-03-01 02:04:45 +01:00
tor_addr_t tar;
if (!cc_list)
return 0;
2012-10-19 23:23:04 +02:00
/* XXXXipv6 */
2012-03-01 02:04:45 +01:00
tor_addr_from_ipv4h(&tar, addr);
country = geoip_get_country_by_addr(&tar);
name = geoip_get_country_name(country);
return smartlist_contains_string_case(cc_list, name);
}
/** Return 1 if <b>addr</b>:<b>port</b> is permitted to publish to our
* directory, based on <b>authdir_reject_policy</b>. Else return 0.
*/
int
authdir_policy_permits_address(uint32_t addr, uint16_t port)
{
if (! addr_policy_permits_address(addr, port, authdir_reject_policy))
return 0;
return !addr_is_in_cc_list(addr, get_options()->AuthDirRejectCCs);
}
/** Return 1 if <b>addr</b>:<b>port</b> is considered valid in our
* directory, based on <b>authdir_invalid_policy</b>. Else return 0.
*/
int
authdir_policy_valid_address(uint32_t addr, uint16_t port)
{
if (! addr_policy_permits_address(addr, port, authdir_invalid_policy))
return 0;
return !addr_is_in_cc_list(addr, get_options()->AuthDirInvalidCCs);
}
/** Return 1 if <b>addr</b>:<b>port</b> should be marked as a bad exit,
* based on <b>authdir_badexit_policy</b>. Else return 0.
*/
int
authdir_policy_badexit_address(uint32_t addr, uint16_t port)
{
if (! addr_policy_permits_address(addr, port, authdir_badexit_policy))
return 1;
return addr_is_in_cc_list(addr, get_options()->AuthDirBadExitCCs);
}
#define REJECT(arg) \
STMT_BEGIN *msg = tor_strdup(arg); goto err; STMT_END
/** Config helper: If there's any problem with the policy configuration
* options in <b>options</b>, return -1 and set <b>msg</b> to a newly
* allocated description of the error. Else return 0. */
int
validate_addr_policies(const or_options_t *options, char **msg)
{
/* XXXX Maybe merge this into parse_policies_from_options, to make sure
* that the two can't go out of sync. */
smartlist_t *addr_policy=NULL;
*msg = NULL;
if (policies_parse_exit_policy_from_options(options,0,NULL,&addr_policy)) {
REJECT("Error in ExitPolicy entry.");
}
static int warned_about_exitrelay = 0;
const int exitrelay_setting_is_auto = options->ExitRelay == -1;
const int policy_accepts_something =
! (policy_is_reject_star(addr_policy, AF_INET) &&
policy_is_reject_star(addr_policy, AF_INET6));
if (server_mode(options) &&
! warned_about_exitrelay &&
exitrelay_setting_is_auto &&
policy_accepts_something) {
/* Policy accepts something */
warned_about_exitrelay = 1;
log_warn(LD_CONFIG,
"Tor is running as an exit relay%s. If you did not want this "
"behavior, please set the ExitRelay option to 0. If you do "
"want to run an exit Relay, please set the ExitRelay option "
"to 1 to disable this warning, and for forward compatibility.",
options->ExitPolicy == NULL ?
" with the default exit policy" : "");
if (options->ExitPolicy == NULL) {
log_warn(LD_CONFIG,
"In a future version of Tor, ExitRelay 0 may become the "
"default when no ExitPolicy is given.");
}
}
/* The rest of these calls *append* to addr_policy. So don't actually
* use the results for anything other than checking if they parse! */
if (parse_addr_policy(options->DirPolicy, &addr_policy, -1))
REJECT("Error in DirPolicy entry.");
if (parse_addr_policy(options->SocksPolicy, &addr_policy, -1))
REJECT("Error in SocksPolicy entry.");
if (parse_addr_policy(options->AuthDirReject, &addr_policy,
ADDR_POLICY_REJECT))
REJECT("Error in AuthDirReject entry.");
if (parse_addr_policy(options->AuthDirInvalid, &addr_policy,
ADDR_POLICY_REJECT))
REJECT("Error in AuthDirInvalid entry.");
if (parse_addr_policy(options->AuthDirBadExit, &addr_policy,
ADDR_POLICY_REJECT))
REJECT("Error in AuthDirBadExit entry.");
if (parse_addr_policy(options->ReachableAddresses, &addr_policy,
ADDR_POLICY_ACCEPT))
REJECT("Error in ReachableAddresses entry.");
if (parse_addr_policy(options->ReachableORAddresses, &addr_policy,
ADDR_POLICY_ACCEPT))
REJECT("Error in ReachableORAddresses entry.");
if (parse_addr_policy(options->ReachableDirAddresses, &addr_policy,
ADDR_POLICY_ACCEPT))
REJECT("Error in ReachableDirAddresses entry.");
2010-08-16 00:29:27 +02:00
err:
addr_policy_list_free(addr_policy);
return *msg ? -1 : 0;
#undef REJECT
}
/** Parse <b>string</b> in the same way that the exit policy
* is parsed, and put the processed version in *<b>policy</b>.
* Ignore port specifiers.
*/
static int
load_policy_from_option(config_line_t *config, const char *option_name,
smartlist_t **policy,
int assume_action)
{
int r;
int killed_any_ports = 0;
addr_policy_list_free(*policy);
*policy = NULL;
r = parse_addr_policy(config, policy, assume_action);
if (r < 0) {
return -1;
}
if (*policy) {
SMARTLIST_FOREACH_BEGIN(*policy, addr_policy_t *, n) {
/* ports aren't used in these. */
if (n->prt_min > 1 || n->prt_max != 65535) {
addr_policy_t newp, *c;
memcpy(&newp, n, sizeof(newp));
newp.prt_min = 1;
newp.prt_max = 65535;
newp.is_canonical = 0;
c = addr_policy_get_canonical_entry(&newp);
SMARTLIST_REPLACE_CURRENT(*policy, n, c);
addr_policy_free(n);
killed_any_ports = 1;
}
} SMARTLIST_FOREACH_END(n);
}
if (killed_any_ports) {
log_warn(LD_CONFIG, "Ignoring ports in %s option.", option_name);
}
return 0;
}
/** Set all policies based on <b>options</b>, which should have been validated
* first by validate_addr_policies. */
int
policies_parse_from_options(const or_options_t *options)
{
int ret = 0;
if (load_policy_from_option(options->SocksPolicy, "SocksPolicy",
&socks_policy, -1) < 0)
ret = -1;
if (load_policy_from_option(options->DirPolicy, "DirPolicy",
&dir_policy, -1) < 0)
ret = -1;
if (load_policy_from_option(options->AuthDirReject, "AuthDirReject",
&authdir_reject_policy, ADDR_POLICY_REJECT) < 0)
ret = -1;
if (load_policy_from_option(options->AuthDirInvalid, "AuthDirInvalid",
&authdir_invalid_policy, ADDR_POLICY_REJECT) < 0)
ret = -1;
if (load_policy_from_option(options->AuthDirBadExit, "AuthDirBadExit",
&authdir_badexit_policy, ADDR_POLICY_REJECT) < 0)
ret = -1;
if (parse_reachable_addresses() < 0)
ret = -1;
return ret;
}
/** Compare two provided address policy items, and return -1, 0, or 1
* if the first is less than, equal to, or greater than the second. */
static int
cmp_single_addr_policy(addr_policy_t *a, addr_policy_t *b)
{
int r;
if ((r=((int)a->policy_type - (int)b->policy_type)))
return r;
if ((r=((int)a->is_private - (int)b->is_private)))
return r;
/* refcnt and is_canonical are irrelevant to equality,
* they are hash table implementation details */
if ((r=tor_addr_compare(&a->addr, &b->addr, CMP_EXACT)))
return r;
if ((r=((int)a->maskbits - (int)b->maskbits)))
return r;
if ((r=((int)a->prt_min - (int)b->prt_min)))
return r;
if ((r=((int)a->prt_max - (int)b->prt_max)))
return r;
return 0;
}
/** Like cmp_single_addr_policy() above, but looks at the
* whole set of policies in each case. */
int
cmp_addr_policies(smartlist_t *a, smartlist_t *b)
{
int r, i;
int len_a = a ? smartlist_len(a) : 0;
int len_b = b ? smartlist_len(b) : 0;
for (i = 0; i < len_a && i < len_b; ++i) {
if ((r = cmp_single_addr_policy(smartlist_get(a, i), smartlist_get(b, i))))
return r;
}
if (i == len_a && i == len_b)
return 0;
if (i < len_a)
return -1;
else
return 1;
}
/** Node in hashtable used to store address policy entries. */
typedef struct policy_map_ent_t {
HT_ENTRY(policy_map_ent_t) node;
addr_policy_t *policy;
} policy_map_ent_t;
/* DOCDOC policy_root */
static HT_HEAD(policy_map, policy_map_ent_t) policy_root = HT_INITIALIZER();
/** Return true iff a and b are equal. */
static inline int
policy_eq(policy_map_ent_t *a, policy_map_ent_t *b)
{
return cmp_single_addr_policy(a->policy, b->policy) == 0;
}
/** Return a hashcode for <b>ent</b> */
static unsigned int
policy_hash(const policy_map_ent_t *ent)
{
const addr_policy_t *a = ent->policy;
addr_policy_t aa;
memset(&aa, 0, sizeof(aa));
aa.prt_min = a->prt_min;
aa.prt_max = a->prt_max;
aa.maskbits = a->maskbits;
aa.policy_type = a->policy_type;
aa.is_private = a->is_private;
if (a->is_private) {
aa.is_private = 1;
} else {
tor_addr_copy_tight(&aa.addr, &a->addr);
}
return (unsigned) siphash24g(&aa, sizeof(aa));
}
HT_PROTOTYPE(policy_map, policy_map_ent_t, node, policy_hash,
policy_eq)
HT_GENERATE2(policy_map, policy_map_ent_t, node, policy_hash,
policy_eq, 0.6, tor_reallocarray_, tor_free_)
/** Given a pointer to an addr_policy_t, return a copy of the pointer to the
* "canonical" copy of that addr_policy_t; the canonical copy is a single
* reference-counted object. */
addr_policy_t *
addr_policy_get_canonical_entry(addr_policy_t *e)
{
policy_map_ent_t search, *found;
if (e->is_canonical)
return e;
search.policy = e;
found = HT_FIND(policy_map, &policy_root, &search);
if (!found) {
found = tor_malloc_zero(sizeof(policy_map_ent_t));
found->policy = tor_memdup(e, sizeof(addr_policy_t));
found->policy->is_canonical = 1;
found->policy->refcnt = 0;
HT_INSERT(policy_map, &policy_root, found);
}
tor_assert(!cmp_single_addr_policy(found->policy, e));
++found->policy->refcnt;
return found->policy;
}
/** Helper for compare_tor_addr_to_addr_policy. Implements the case where
* addr and port are both known. */
static addr_policy_result_t
compare_known_tor_addr_to_addr_policy(const tor_addr_t *addr, uint16_t port,
const smartlist_t *policy)
{
/* We know the address and port, and we know the policy, so we can just
* compute an exact match. */
SMARTLIST_FOREACH_BEGIN(policy, addr_policy_t *, tmpe) {
if (tmpe->addr.family == AF_UNSPEC) {
log_warn(LD_BUG, "Policy contains an AF_UNSPEC address, which only "
"matches other AF_UNSPEC addresses.");
}
/* Address is known */
if (!tor_addr_compare_masked(addr, &tmpe->addr, tmpe->maskbits,
CMP_EXACT)) {
if (port >= tmpe->prt_min && port <= tmpe->prt_max) {
/* Exact match for the policy */
return tmpe->policy_type == ADDR_POLICY_ACCEPT ?
ADDR_POLICY_ACCEPTED : ADDR_POLICY_REJECTED;
}
}
} SMARTLIST_FOREACH_END(tmpe);
/* accept all by default. */
return ADDR_POLICY_ACCEPTED;
}
/** Helper for compare_tor_addr_to_addr_policy. Implements the case where
* addr is known but port is not. */
static addr_policy_result_t
compare_known_tor_addr_to_addr_policy_noport(const tor_addr_t *addr,
const smartlist_t *policy)
{
/* We look to see if there's a definite match. If so, we return that
match's value, unless there's an intervening possible match that says
something different. */
int maybe_accept = 0, maybe_reject = 0;
SMARTLIST_FOREACH_BEGIN(policy, addr_policy_t *, tmpe) {
if (tmpe->addr.family == AF_UNSPEC) {
log_warn(LD_BUG, "Policy contains an AF_UNSPEC address, which only "
"matches other AF_UNSPEC addresses.");
}
if (!tor_addr_compare_masked(addr, &tmpe->addr, tmpe->maskbits,
CMP_EXACT)) {
if (tmpe->prt_min <= 1 && tmpe->prt_max >= 65535) {
/* Definitely matches, since it covers all ports. */
if (tmpe->policy_type == ADDR_POLICY_ACCEPT) {
/* If we already hit a clause that might trigger a 'reject', than we
* can't be sure of this certain 'accept'.*/
return maybe_reject ? ADDR_POLICY_PROBABLY_ACCEPTED :
ADDR_POLICY_ACCEPTED;
} else {
return maybe_accept ? ADDR_POLICY_PROBABLY_REJECTED :
ADDR_POLICY_REJECTED;
}
} else {
/* Might match. */
if (tmpe->policy_type == ADDR_POLICY_REJECT)
maybe_reject = 1;
else
maybe_accept = 1;
}
}
} SMARTLIST_FOREACH_END(tmpe);
/* accept all by default. */
return maybe_reject ? ADDR_POLICY_PROBABLY_ACCEPTED : ADDR_POLICY_ACCEPTED;
}
/** Helper for compare_tor_addr_to_addr_policy. Implements the case where
* port is known but address is not. */
static addr_policy_result_t
compare_unknown_tor_addr_to_addr_policy(uint16_t port,
const smartlist_t *policy)
{
/* We look to see if there's a definite match. If so, we return that
match's value, unless there's an intervening possible match that says
something different. */
int maybe_accept = 0, maybe_reject = 0;
SMARTLIST_FOREACH_BEGIN(policy, addr_policy_t *, tmpe) {
if (tmpe->addr.family == AF_UNSPEC) {
log_warn(LD_BUG, "Policy contains an AF_UNSPEC address, which only "
"matches other AF_UNSPEC addresses.");
}
if (tmpe->prt_min <= port && port <= tmpe->prt_max) {
2012-02-29 19:17:52 +01:00
if (tmpe->maskbits == 0) {
/* Definitely matches, since it covers all addresses. */
if (tmpe->policy_type == ADDR_POLICY_ACCEPT) {
/* If we already hit a clause that might trigger a 'reject', than we
* can't be sure of this certain 'accept'.*/
return maybe_reject ? ADDR_POLICY_PROBABLY_ACCEPTED :
ADDR_POLICY_ACCEPTED;
} else {
return maybe_accept ? ADDR_POLICY_PROBABLY_REJECTED :
ADDR_POLICY_REJECTED;
}
} else {
/* Might match. */
if (tmpe->policy_type == ADDR_POLICY_REJECT)
maybe_reject = 1;
else
maybe_accept = 1;
}
}
} SMARTLIST_FOREACH_END(tmpe);
/* accept all by default. */
return maybe_reject ? ADDR_POLICY_PROBABLY_ACCEPTED : ADDR_POLICY_ACCEPTED;
}
/** Decide whether a given addr:port is definitely accepted,
* definitely rejected, probably accepted, or probably rejected by a
* given policy. If <b>addr</b> is 0, we don't know the IP of the
* target address. If <b>port</b> is 0, we don't know the port of the
* target address. (At least one of <b>addr</b> and <b>port</b> must be
* provided. If you want to know whether a policy would definitely reject
* an unknown address:port, use policy_is_reject_star().)
*
* We could do better by assuming that some ranges never match typical
* addresses (127.0.0.1, and so on). But we'll try this for now.
*/
MOCK_IMPL(addr_policy_result_t,
compare_tor_addr_to_addr_policy,(const tor_addr_t *addr, uint16_t port,
const smartlist_t *policy))
{
if (!policy) {
/* no policy? accept all. */
return ADDR_POLICY_ACCEPTED;
} else if (addr == NULL || tor_addr_is_null(addr)) {
if (port == 0) {
log_info(LD_BUG, "Rejecting null address with 0 port (family %d)",
addr ? tor_addr_family(addr) : -1);
return ADDR_POLICY_REJECTED;
}
return compare_unknown_tor_addr_to_addr_policy(port, policy);
} else if (port == 0) {
return compare_known_tor_addr_to_addr_policy_noport(addr, policy);
} else {
return compare_known_tor_addr_to_addr_policy(addr, port, policy);
}
}
/** Return true iff the address policy <b>a</b> covers every case that
* would be covered by <b>b</b>, so that a,b is redundant. */
static int
addr_policy_covers(addr_policy_t *a, addr_policy_t *b)
{
if (tor_addr_family(&a->addr) != tor_addr_family(&b->addr)) {
/* You can't cover a different family. */
return 0;
}
/* We can ignore accept/reject, since "accept *:80, reject *:80" reduces
* to "accept *:80". */
if (a->maskbits > b->maskbits) {
/* a has more fixed bits than b; it can't possibly cover b. */
return 0;
}
if (tor_addr_compare_masked(&a->addr, &b->addr, a->maskbits, CMP_EXACT)) {
/* There's a fixed bit in a that's set differently in b. */
return 0;
}
return (a->prt_min <= b->prt_min && a->prt_max >= b->prt_max);
}
/** Return true iff the address policies <b>a</b> and <b>b</b> intersect,
* that is, there exists an address/port that is covered by <b>a</b> that
* is also covered by <b>b</b>.
*/
static int
addr_policy_intersects(addr_policy_t *a, addr_policy_t *b)
{
maskbits_t minbits;
/* All the bits we care about are those that are set in both
* netmasks. If they are equal in a and b's networkaddresses
* then the networks intersect. If there is a difference,
* then they do not. */
if (a->maskbits < b->maskbits)
minbits = a->maskbits;
else
minbits = b->maskbits;
if (tor_addr_compare_masked(&a->addr, &b->addr, minbits, CMP_EXACT))
return 0;
if (a->prt_max < b->prt_min || b->prt_max < a->prt_min)
return 0;
return 1;
}
/** Add the exit policy described by <b>more</b> to <b>policy</b>.
*/
STATIC void
append_exit_policy_string(smartlist_t **policy, const char *more)
{
config_line_t tmp;
tmp.key = NULL;
tmp.value = (char*) more;
tmp.next = NULL;
if (parse_addr_policy(&tmp, policy, -1)<0) {
log_warn(LD_BUG, "Unable to parse internally generated policy %s",more);
}
}
/** Add "reject <b>addr</b>:*" to <b>dest</b>, creating the list as needed. */
void
addr_policy_append_reject_addr(smartlist_t **dest, const tor_addr_t *addr)
{
tor_assert(dest);
tor_assert(addr);
addr_policy_t p, *add;
memset(&p, 0, sizeof(p));
p.policy_type = ADDR_POLICY_REJECT;
p.maskbits = tor_addr_family(addr) == AF_INET6 ? 128 : 32;
tor_addr_copy(&p.addr, addr);
p.prt_min = 1;
p.prt_max = 65535;
add = addr_policy_get_canonical_entry(&p);
if (!*dest)
*dest = smartlist_new();
smartlist_add(*dest, add);
log_debug(LD_CONFIG, "Adding a reject ExitPolicy 'reject %s:*'",
fmt_addr(addr));
}
/* Is addr public for the purposes of rejection? */
static int
tor_addr_is_public_for_reject(const tor_addr_t *addr)
{
return (!tor_addr_is_null(addr) && !tor_addr_is_internal(addr, 0)
&& !tor_addr_is_multicast(addr));
}
/* Add "reject <b>addr</b>:*" to <b>dest</b>, creating the list as needed.
* Filter the address, only adding an IPv4 reject rule if ipv4_rules
* is true, and similarly for ipv6_rules. Check each address returns true for
* tor_addr_is_public_for_reject before adding it.
*/
static void
addr_policy_append_reject_addr_filter(smartlist_t **dest,
const tor_addr_t *addr,
int ipv4_rules,
int ipv6_rules)
{
tor_assert(dest);
tor_assert(addr);
/* Only reject IP addresses which are public */
if (tor_addr_is_public_for_reject(addr)) {
/* Reject IPv4 addresses and IPv6 addresses based on the filters */
int is_ipv4 = tor_addr_is_v4(addr);
if ((is_ipv4 && ipv4_rules) || (!is_ipv4 && ipv6_rules)) {
addr_policy_append_reject_addr(dest, addr);
}
}
}
/** Add "reject addr:*" to <b>dest</b>, for each addr in addrs, creating the
* list as needed. */
void
addr_policy_append_reject_addr_list(smartlist_t **dest,
const smartlist_t *addrs)
{
tor_assert(dest);
tor_assert(addrs);
SMARTLIST_FOREACH_BEGIN(addrs, tor_addr_t *, addr) {
addr_policy_append_reject_addr(dest, addr);
} SMARTLIST_FOREACH_END(addr);
}
/** Add "reject addr:*" to <b>dest</b>, for each addr in addrs, creating the
* list as needed. Filter using */
static void
addr_policy_append_reject_addr_list_filter(smartlist_t **dest,
const smartlist_t *addrs,
int ipv4_rules,
int ipv6_rules)
{
tor_assert(dest);
tor_assert(addrs);
SMARTLIST_FOREACH_BEGIN(addrs, tor_addr_t *, addr) {
addr_policy_append_reject_addr_filter(dest, addr, ipv4_rules, ipv6_rules);
} SMARTLIST_FOREACH_END(addr);
}
/** Detect and excise "dead code" from the policy *<b>dest</b>. */
static void
exit_policy_remove_redundancies(smartlist_t *dest)
{
addr_policy_t *ap, *tmp;
int i, j;
/* Step one: kill every ipv4 thing after *4:*, every IPv6 thing after *6:*
*/
{
int kill_v4=0, kill_v6=0;
for (i = 0; i < smartlist_len(dest); ++i) {
sa_family_t family;
ap = smartlist_get(dest, i);
family = tor_addr_family(&ap->addr);
if ((family == AF_INET && kill_v4) ||
(family == AF_INET6 && kill_v6)) {
smartlist_del_keeporder(dest, i--);
addr_policy_free(ap);
continue;
}
if (ap->maskbits == 0 && ap->prt_min <= 1 && ap->prt_max >= 65535) {
/* This is a catch-all line -- later lines are unreachable. */
if (family == AF_INET) {
kill_v4 = 1;
} else if (family == AF_INET6) {
kill_v6 = 1;
}
}
}
}
/* Step two: for every entry, see if there's a redundant entry
* later on, and remove it. */
for (i = 0; i < smartlist_len(dest)-1; ++i) {
ap = smartlist_get(dest, i);
for (j = i+1; j < smartlist_len(dest); ++j) {
tmp = smartlist_get(dest, j);
tor_assert(j > i);
if (addr_policy_covers(ap, tmp)) {
char p1[POLICY_BUF_LEN], p2[POLICY_BUF_LEN];
policy_write_item(p1, sizeof(p1), tmp, 0);
policy_write_item(p2, sizeof(p2), ap, 0);
log_debug(LD_CONFIG, "Removing exit policy %s (%d). It is made "
"redundant by %s (%d).", p1, j, p2, i);
smartlist_del_keeporder(dest, j--);
addr_policy_free(tmp);
}
}
}
/* Step three: for every entry A, see if there's an entry B making this one
* redundant later on. This is the case if A and B are of the same type
* (accept/reject), A is a subset of B, and there is no other entry of
* different type in between those two that intersects with A.
*
2009-05-27 23:55:51 +02:00
* Anybody want to double-check the logic here? XXX
*/
for (i = 0; i < smartlist_len(dest)-1; ++i) {
ap = smartlist_get(dest, i);
for (j = i+1; j < smartlist_len(dest); ++j) {
// tor_assert(j > i); // j starts out at i+1; j only increases; i only
// // decreases.
tmp = smartlist_get(dest, j);
if (ap->policy_type != tmp->policy_type) {
if (addr_policy_intersects(ap, tmp))
break;
} else { /* policy_types are equal. */
if (addr_policy_covers(tmp, ap)) {
char p1[POLICY_BUF_LEN], p2[POLICY_BUF_LEN];
policy_write_item(p1, sizeof(p1), ap, 0);
policy_write_item(p2, sizeof(p2), tmp, 0);
log_debug(LD_CONFIG, "Removing exit policy %s. It is already "
2007-12-01 00:32:25 +01:00
"covered by %s.", p1, p2);
smartlist_del_keeporder(dest, i--);
addr_policy_free(ap);
break;
}
}
}
}
}
/** Reject private helper for policies_parse_exit_policy_internal: rejects
* publicly routable addresses on this exit relay.
*
* Add reject entries to the linked list *<b>dest</b>:
* <ul>
* <li>if configured_addresses is non-NULL, add entries that reject each
* tor_addr_t in the list as a destination.
* <li>if reject_interface_addresses is true, add entries that reject each
* public IPv4 and IPv6 address of each interface on this machine.
* <li>if reject_configured_port_addresses is true, add entries that reject
* each IPv4 and IPv6 address configured for a port.
* </ul>
*
* IPv6 entries are only added if ipv6_exit is true. (All IPv6 addresses are
* already blocked by policies_parse_exit_policy_internal if ipv6_exit is
* false.)
*
* The list in <b>dest</b> is created as needed.
*/
void
policies_parse_exit_policy_reject_private(
smartlist_t **dest,
int ipv6_exit,
const smartlist_t *configured_addresses,
int reject_interface_addresses,
int reject_configured_port_addresses)
{
tor_assert(dest);
/* Reject configured addresses, if they are from public netblocks. */
if (configured_addresses) {
addr_policy_append_reject_addr_list_filter(dest, configured_addresses,
1, ipv6_exit);
}
/* Reject configured port addresses, if they are from public netblocks. */
if (reject_configured_port_addresses) {
const smartlist_t *port_addrs = get_configured_ports();
SMARTLIST_FOREACH_BEGIN(port_addrs, port_cfg_t *, port) {
/* Only reject port IP addresses, not port unix sockets */
if (!port->is_unix_addr) {
addr_policy_append_reject_addr_filter(dest, &port->addr, 1, ipv6_exit);
}
} SMARTLIST_FOREACH_END(port);
}
/* Reject local addresses from public netblocks on any interface. */
if (reject_interface_addresses) {
smartlist_t *public_addresses = NULL;
/* Reject public IPv4 addresses on any interface */
public_addresses = get_interface_address6_list(LOG_INFO, AF_INET, 0);
addr_policy_append_reject_addr_list_filter(dest, public_addresses, 1, 0);
free_interface_address6_list(public_addresses);
/* Don't look for IPv6 addresses if we're configured as IPv4-only */
if (ipv6_exit) {
/* Reject public IPv6 addresses on any interface */
public_addresses = get_interface_address6_list(LOG_INFO, AF_INET6, 0);
addr_policy_append_reject_addr_list_filter(dest, public_addresses, 0, 1);
free_interface_address6_list(public_addresses);
}
}
/* If addresses were added multiple times, remove all but one of them. */
if (*dest) {
exit_policy_remove_redundancies(*dest);
}
}
/**
* Iterate through <b>policy</b> looking for redundant entries. Log a
* warning message with the first redundant entry, if any is found.
*/
static void
policies_log_first_redundant_entry(const smartlist_t *policy)
{
int found_final_effective_entry = 0;
int first_redundant_entry = 0;
tor_assert(policy);
SMARTLIST_FOREACH_BEGIN(policy, const addr_policy_t *, p) {
sa_family_t family;
int found_ipv4_wildcard = 0, found_ipv6_wildcard = 0;
const int i = p_sl_idx;
/* Look for accept/reject *[4|6|]:* entires */
if (p->prt_min <= 1 && p->prt_max == 65535 && p->maskbits == 0) {
family = tor_addr_family(&p->addr);
/* accept/reject *:* may have already been expanded into
* accept/reject *4:*,accept/reject *6:*
* But handle both forms.
*/
if (family == AF_INET || family == AF_UNSPEC) {
found_ipv4_wildcard = 1;
}
if (family == AF_INET6 || family == AF_UNSPEC) {
found_ipv6_wildcard = 1;
}
}
/* We also find accept *4:*,reject *6:* ; and
* accept *4:*,<other policies>,accept *6:* ; and similar.
* That's ok, because they make any subsequent entries redundant. */
if (found_ipv4_wildcard && found_ipv6_wildcard) {
found_final_effective_entry = 1;
/* if we're not on the final entry in the list */
if (i < smartlist_len(policy) - 1) {
first_redundant_entry = i + 1;
}
break;
}
} SMARTLIST_FOREACH_END(p);
/* Work out if there are redundant trailing entries in the policy list */
if (found_final_effective_entry && first_redundant_entry > 0) {
const addr_policy_t *p;
/* Longest possible policy is
* "accept6 ffff:ffff:..255/128:10000-65535",
* which contains a max-length IPv6 address, plus 24 characters. */
char line[TOR_ADDR_BUF_LEN + 32];
tor_assert(first_redundant_entry < smartlist_len(policy));
p = smartlist_get(policy, first_redundant_entry);
/* since we've already parsed the policy into an addr_policy_t struct,
* we might not log exactly what the user typed in */
policy_write_item(line, TOR_ADDR_BUF_LEN + 32, p, 0);
log_warn(LD_DIR, "Exit policy '%s' and all following policies are "
"redundant, as it follows accept/reject *:* rules for both "
"IPv4 and IPv6. They will be removed from the exit policy. (Use "
"accept/reject *:* as the last entry in any exit policy.)",
line);
}
}
#define DEFAULT_EXIT_POLICY \
"reject *:25,reject *:119,reject *:135-139,reject *:445," \
"reject *:563,reject *:1214,reject *:4661-4666," \
"reject *:6346-6429,reject *:6699,reject *:6881-6999,accept *:*"
/** Parse the exit policy <b>cfg</b> into the linked list *<b>dest</b>.
*
* If <b>ipv6_exit</b> is false, prepend "reject *6:*" to the policy.
*
* If <b>rejectprivate</b> is true:
* - prepend "reject private:*" to the policy.
* - prepend entries that reject publicly routable addresses on this exit
* relay by calling policies_parse_exit_policy_reject_private
*
* If cfg doesn't end in an absolute accept or reject and if
* <b>add_default_policy</b> is true, add the default exit
* policy afterwards.
*
* Return -1 if we can't parse cfg, else return 0.
*
* This function is used to parse the exit policy from our torrc. For
* the functions used to parse the exit policy from a router descriptor,
* see router_add_exit_policy.
*/
static int
policies_parse_exit_policy_internal(config_line_t *cfg,
smartlist_t **dest,
int ipv6_exit,
2014-09-14 16:07:05 +02:00
int rejectprivate,
const smartlist_t *configured_addresses,
int reject_interface_addresses,
int reject_configured_port_addresses,
int add_default_policy)
{
if (!ipv6_exit) {
append_exit_policy_string(dest, "reject *6:*");
}
if (rejectprivate) {
/* Reject IPv4 and IPv6 reserved private netblocks */
append_exit_policy_string(dest, "reject private:*");
/* Reject IPv4 and IPv6 publicly routable addresses on this exit relay */
policies_parse_exit_policy_reject_private(
dest, ipv6_exit,
configured_addresses,
reject_interface_addresses,
reject_configured_port_addresses);
}
if (parse_addr_policy(cfg, dest, -1))
return -1;
/* Before we add the default policy and final rejects, check to see if
* there are any lines after accept *:* or reject *:*. These lines have no
* effect, and are most likely an error. */
policies_log_first_redundant_entry(*dest);
if (add_default_policy) {
append_exit_policy_string(dest, DEFAULT_EXIT_POLICY);
} else {
append_exit_policy_string(dest, "reject *4:*");
append_exit_policy_string(dest, "reject *6:*");
}
exit_policy_remove_redundancies(*dest);
return 0;
}
/** Parse exit policy in <b>cfg</b> into <b>dest</b> smartlist.
*
* Prepend an entry that rejects all IPv6 destinations unless
* <b>EXIT_POLICY_IPV6_ENABLED</b> bit is set in <b>options</b> bitmask.
*
* If <b>EXIT_POLICY_REJECT_PRIVATE</b> bit is set in <b>options</b>:
* - prepend an entry that rejects all destinations in all netblocks
* reserved for private use.
* - prepend entries that reject publicly routable addresses on this exit
* relay by calling policies_parse_exit_policy_internal
*
* If <b>EXIT_POLICY_ADD_DEFAULT</b> bit is set in <b>options</b>, append
* default exit policy entries to <b>result</b> smartlist.
*/
2014-09-14 16:07:05 +02:00
int
policies_parse_exit_policy(config_line_t *cfg, smartlist_t **dest,
exit_policy_parser_cfg_t options,
const smartlist_t *configured_addresses)
{
int ipv6_enabled = (options & EXIT_POLICY_IPV6_ENABLED) ? 1 : 0;
int reject_private = (options & EXIT_POLICY_REJECT_PRIVATE) ? 1 : 0;
int add_default = (options & EXIT_POLICY_ADD_DEFAULT) ? 1 : 0;
return policies_parse_exit_policy_internal(cfg,dest,ipv6_enabled,
reject_private,
configured_addresses,
reject_private,
reject_private,
add_default);
}
/** Helper function that adds a copy of addr to a smartlist as long as it is
* non-NULL and not tor_addr_is_null().
*
* The caller is responsible for freeing all the tor_addr_t* in the smartlist.
*/
static void
policies_copy_addr_to_smartlist(smartlist_t *addr_list, const tor_addr_t *addr)
{
if (addr && !tor_addr_is_null(addr)) {
tor_addr_t *addr_copy = tor_malloc(sizeof(tor_addr_t));
tor_addr_copy(addr_copy, addr);
smartlist_add(addr_list, addr_copy);
}
}
/** Helper function that adds ipv4h_addr to a smartlist as a tor_addr_t *,
* as long as it is not tor_addr_is_null(), by converting it to a tor_addr_t
* and passing it to policies_add_addr_to_smartlist.
*
* The caller is responsible for freeing all the tor_addr_t* in the smartlist.
*/
static void
policies_copy_ipv4h_to_smartlist(smartlist_t *addr_list, uint32_t ipv4h_addr)
{
if (ipv4h_addr) {
tor_addr_t ipv4_tor_addr;
tor_addr_from_ipv4h(&ipv4_tor_addr, ipv4h_addr);
policies_copy_addr_to_smartlist(addr_list, &ipv4_tor_addr);
}
}
/** Helper function that adds copies of
* or_options->OutboundBindAddressIPv[4|6]_ to a smartlist as tor_addr_t *, as
* long as or_options is non-NULL, and the addresses are not
* tor_addr_is_null(), by passing them to policies_add_addr_to_smartlist.
*
* The caller is responsible for freeing all the tor_addr_t* in the smartlist.
*/
static void
policies_copy_outbound_addresses_to_smartlist(smartlist_t *addr_list,
const or_options_t *or_options)
{
if (or_options) {
policies_copy_addr_to_smartlist(addr_list,
&or_options->OutboundBindAddressIPv4_);
policies_copy_addr_to_smartlist(addr_list,
&or_options->OutboundBindAddressIPv6_);
}
}
/** Parse <b>ExitPolicy</b> member of <b>or_options</b> into <b>result</b>
* smartlist.
* If <b>or_options->IPv6Exit</b> is false, prepend an entry that
* rejects all IPv6 destinations.
*
* If <b>or_options->ExitPolicyRejectPrivate</b> is true:
* - prepend an entry that rejects all destinations in all netblocks reserved
* for private use.
* - if local_address is non-zero, treat it as a host-order IPv4 address, and
* add it to the list of configured addresses.
* - if ipv6_local_address is non-NULL, and not the null tor_addr_t, add it
* to the list of configured addresses.
* - if or_options->OutboundBindAddressIPv4_ is not the null tor_addr_t, add
* it to the list of configured addresses.
* - if or_options->OutboundBindAddressIPv6_ is not the null tor_addr_t, add
* it to the list of configured addresses.
*
* If <b>or_options->BridgeRelay</b> is false, append entries of default
* Tor exit policy into <b>result</b> smartlist.
*
* If or_options->ExitRelay is false, then make our exit policy into
* "reject *:*" regardless.
*/
int
policies_parse_exit_policy_from_options(const or_options_t *or_options,
uint32_t local_address,
const tor_addr_t *ipv6_local_address,
smartlist_t **result)
{
exit_policy_parser_cfg_t parser_cfg = 0;
smartlist_t *configured_addresses = NULL;
int rv = 0;
/* Short-circuit for non-exit relays */
if (or_options->ExitRelay == 0) {
append_exit_policy_string(result, "reject *4:*");
append_exit_policy_string(result, "reject *6:*");
return 0;
}
configured_addresses = smartlist_new();
/* Configure the parser */
if (or_options->IPv6Exit) {
parser_cfg |= EXIT_POLICY_IPV6_ENABLED;
}
if (or_options->ExitPolicyRejectPrivate) {
parser_cfg |= EXIT_POLICY_REJECT_PRIVATE;
}
if (!or_options->BridgeRelay) {
parser_cfg |= EXIT_POLICY_ADD_DEFAULT;
}
/* Copy the configured addresses into the tor_addr_t* list */
policies_copy_ipv4h_to_smartlist(configured_addresses, local_address);
policies_copy_addr_to_smartlist(configured_addresses, ipv6_local_address);
policies_copy_outbound_addresses_to_smartlist(configured_addresses,
or_options);
rv = policies_parse_exit_policy(or_options->ExitPolicy, result, parser_cfg,
configured_addresses);
SMARTLIST_FOREACH(configured_addresses, tor_addr_t *, a, tor_free(a));
smartlist_free(configured_addresses);
return rv;
}
/** Add "reject *:*" to the end of the policy in *<b>dest</b>, allocating
* *<b>dest</b> as needed. */
void
policies_exit_policy_append_reject_star(smartlist_t **dest)
{
append_exit_policy_string(dest, "reject *4:*");
append_exit_policy_string(dest, "reject *6:*");
}
Initial conversion to use node_t throughout our codebase. A node_t is an abstraction over routerstatus_t, routerinfo_t, and microdesc_t. It should try to present a consistent interface to all of them. There should be a node_t for a server whenever there is * A routerinfo_t for it in the routerlist * A routerstatus_t in the current_consensus. (note that a microdesc_t alone isn't enough to make a node_t exist, since microdescriptors aren't usable on their own.) There are three ways to get a node_t right now: looking it up by ID, looking it up by nickname, and iterating over the whole list of microdescriptors. All (or nearly all) functions that are supposed to return "a router" -- especially those used in building connections and circuits -- should return a node_t, not a routerinfo_t or a routerstatus_t. A node_t should hold all the *mutable* flags about a node. This patch moves the is_foo flags from routerinfo_t into node_t. The flags in routerstatus_t remain, but they get set from the consensus and should not change. Some other highlights of this patch are: * Looking up routerinfo and routerstatus by nickname is now unified and based on the "look up a node by nickname" function. This tries to look only at the values from current consensus, and not get confused by the routerinfo_t->is_named flag, which could get set for other weird reasons. This changes the behavior of how authorities (when acting as clients) deal with nodes that have been listed by nickname. * I tried not to artificially increase the size of the diff here by moving functions around. As a result, some functions that now operate on nodes are now in the wrong file -- they should get moved to nodelist.c once this refactoring settles down. This moving should happen as part of a patch that moves functions AND NOTHING ELSE. * Some old code is now left around inside #if 0/1 blocks, and should get removed once I've verified that I don't want it sitting around to see how we used to do things. There are still some unimplemented functions: these are flagged with "UNIMPLEMENTED_NODELIST()." I'll work on filling in the implementation here, piece by piece. I wish this patch could have been smaller, but there did not seem to be any piece of it that was independent from the rest. Moving flags forces many functions that once returned routerinfo_t * to return node_t *, which forces their friends to change, and so on.
2010-09-29 21:00:41 +02:00
/** Replace the exit policy of <b>node</b> with reject *:* */
void
policies_set_node_exitpolicy_to_reject_all(node_t *node)
{
node->rejects_all = 1;
Initial conversion to use node_t throughout our codebase. A node_t is an abstraction over routerstatus_t, routerinfo_t, and microdesc_t. It should try to present a consistent interface to all of them. There should be a node_t for a server whenever there is * A routerinfo_t for it in the routerlist * A routerstatus_t in the current_consensus. (note that a microdesc_t alone isn't enough to make a node_t exist, since microdescriptors aren't usable on their own.) There are three ways to get a node_t right now: looking it up by ID, looking it up by nickname, and iterating over the whole list of microdescriptors. All (or nearly all) functions that are supposed to return "a router" -- especially those used in building connections and circuits -- should return a node_t, not a routerinfo_t or a routerstatus_t. A node_t should hold all the *mutable* flags about a node. This patch moves the is_foo flags from routerinfo_t into node_t. The flags in routerstatus_t remain, but they get set from the consensus and should not change. Some other highlights of this patch are: * Looking up routerinfo and routerstatus by nickname is now unified and based on the "look up a node by nickname" function. This tries to look only at the values from current consensus, and not get confused by the routerinfo_t->is_named flag, which could get set for other weird reasons. This changes the behavior of how authorities (when acting as clients) deal with nodes that have been listed by nickname. * I tried not to artificially increase the size of the diff here by moving functions around. As a result, some functions that now operate on nodes are now in the wrong file -- they should get moved to nodelist.c once this refactoring settles down. This moving should happen as part of a patch that moves functions AND NOTHING ELSE. * Some old code is now left around inside #if 0/1 blocks, and should get removed once I've verified that I don't want it sitting around to see how we used to do things. There are still some unimplemented functions: these are flagged with "UNIMPLEMENTED_NODELIST()." I'll work on filling in the implementation here, piece by piece. I wish this patch could have been smaller, but there did not seem to be any piece of it that was independent from the rest. Moving flags forces many functions that once returned routerinfo_t * to return node_t *, which forces their friends to change, and so on.
2010-09-29 21:00:41 +02:00
}
/** Return 1 if there is at least one /8 subnet in <b>policy</b> that
* allows exiting to <b>port</b>. Otherwise, return 0. */
static int
exit_policy_is_general_exit_helper(smartlist_t *policy, int port)
{
uint32_t mask, ip, i;
/* Is this /8 rejected (1), or undecided (0)? */
char subnet_status[256];
memset(subnet_status, 0, sizeof(subnet_status));
SMARTLIST_FOREACH_BEGIN(policy, addr_policy_t *, p) {
if (tor_addr_family(&p->addr) != AF_INET)
continue; /* IPv4 only for now */
if (p->prt_min > port || p->prt_max < port)
continue; /* Doesn't cover our port. */
mask = 0;
tor_assert(p->maskbits <= 32);
if (p->maskbits)
mask = UINT32_MAX<<(32-p->maskbits);
ip = tor_addr_to_ipv4h(&p->addr);
/* Calculate the first and last subnet that this exit policy touches
* and set it as loop boundaries. */
for (i = ((mask & ip)>>24); i <= (~((mask & ip) ^ mask)>>24); ++i) {
tor_addr_t addr;
if (subnet_status[i] != 0)
continue; /* We already reject some part of this /8 */
tor_addr_from_ipv4h(&addr, i<<24);
if (tor_addr_is_internal(&addr, 0))
continue; /* Local or non-routable addresses */
if (p->policy_type == ADDR_POLICY_ACCEPT) {
if (p->maskbits > 8)
continue; /* Narrower than a /8. */
/* We found an allowed subnet of at least size /8. Done
* for this port! */
return 1;
} else if (p->policy_type == ADDR_POLICY_REJECT) {
subnet_status[i] = 1;
}
}
} SMARTLIST_FOREACH_END(p);
return 0;
}
/** Return true iff <b>ri</b> is "useful as an exit node", meaning
* it allows exit to at least one /8 address space for at least
* two of ports 80, 443, and 6667. */
int
exit_policy_is_general_exit(smartlist_t *policy)
{
static const int ports[] = { 80, 443, 6667 };
int n_allowed = 0;
int i;
if (!policy) /*XXXX disallow NULL policies? */
return 0;
for (i = 0; i < 3; ++i) {
n_allowed += exit_policy_is_general_exit_helper(policy, ports[i]);
}
return n_allowed >= 2;
}
/** Return false if <b>policy</b> might permit access to some addr:port;
* otherwise if we are certain it rejects everything, return true. */
int
policy_is_reject_star(const smartlist_t *policy, sa_family_t family)
{
if (!policy) /*XXXX disallow NULL policies? */
return 1;
SMARTLIST_FOREACH_BEGIN(policy, addr_policy_t *, p) {
if (p->policy_type == ADDR_POLICY_ACCEPT &&
(tor_addr_family(&p->addr) == family ||
tor_addr_family(&p->addr) == AF_UNSPEC)) {
return 0;
} else if (p->policy_type == ADDR_POLICY_REJECT &&
p->prt_min <= 1 && p->prt_max == 65535 &&
p->maskbits == 0 &&
(tor_addr_family(&p->addr) == family ||
tor_addr_family(&p->addr) == AF_UNSPEC)) {
return 1;
}
} SMARTLIST_FOREACH_END(p);
return 1;
}
/** Write a single address policy to the buf_len byte buffer at buf. Return
* the number of characters written, or -1 on failure. */
int
policy_write_item(char *buf, size_t buflen, const addr_policy_t *policy,
int format_for_desc)
{
size_t written = 0;
char addrbuf[TOR_ADDR_BUF_LEN];
const char *addrpart;
int result;
const int is_accept = policy->policy_type == ADDR_POLICY_ACCEPT;
const sa_family_t family = tor_addr_family(&policy->addr);
const int is_ip6 = (family == AF_INET6);
tor_addr_to_str(addrbuf, &policy->addr, sizeof(addrbuf), 1);
/* write accept/reject 1.2.3.4 */
if (policy->is_private) {
addrpart = "private";
} else if (policy->maskbits == 0) {
if (format_for_desc)
addrpart = "*";
else if (family == AF_INET6)
addrpart = "*6";
else if (family == AF_INET)
addrpart = "*4";
else
addrpart = "*";
} else {
addrpart = addrbuf;
}
result = tor_snprintf(buf, buflen, "%s%s %s",
is_accept ? "accept" : "reject",
(is_ip6&&format_for_desc)?"6":"",
addrpart);
if (result < 0)
return -1;
written += strlen(buf);
/* If the maskbits is 32 (IPv4) or 128 (IPv6) we don't need to give it. If
the mask is 0, we already wrote "*". */
if (policy->maskbits < (is_ip6?128:32) && policy->maskbits > 0) {
if (tor_snprintf(buf+written, buflen-written, "/%d", policy->maskbits)<0)
return -1;
written += strlen(buf+written);
}
if (policy->prt_min <= 1 && policy->prt_max == 65535) {
/* There is no port set; write ":*" */
if (written+4 > buflen)
return -1;
strlcat(buf+written, ":*", buflen-written);
written += 2;
} else if (policy->prt_min == policy->prt_max) {
/* There is only one port; write ":80". */
result = tor_snprintf(buf+written, buflen-written, ":%d", policy->prt_min);
if (result<0)
return -1;
written += result;
} else {
/* There is a range of ports; write ":79-80". */
result = tor_snprintf(buf+written, buflen-written, ":%d-%d",
policy->prt_min, policy->prt_max);
if (result<0)
return -1;
written += result;
}
if (written < buflen)
buf[written] = '\0';
else
return -1;
return (int)written;
}
/** Create a new exit policy summary, initially only with a single
* port 1-64k item */
/* XXXX This entire thing will do most stuff in O(N^2), or worse. Use an
* RB-tree if that turns out to matter. */
static smartlist_t *
policy_summary_create(void)
{
smartlist_t *summary;
policy_summary_item_t* item;
item = tor_malloc_zero(sizeof(policy_summary_item_t));
item->prt_min = 1;
item->prt_max = 65535;
item->reject_count = 0;
item->accepted = 0;
summary = smartlist_new();
smartlist_add(summary, item);
return summary;
}
/** Split the summary item in <b>item</b> at the port <b>new_starts</b>.
* The current item is changed to end at new-starts - 1, the new item
* copies reject_count and accepted from the old item,
* starts at new_starts and ends at the port where the original item
* previously ended.
*/
static policy_summary_item_t*
policy_summary_item_split(policy_summary_item_t* old, uint16_t new_starts)
{
policy_summary_item_t* new;
new = tor_malloc_zero(sizeof(policy_summary_item_t));
new->prt_min = new_starts;
new->prt_max = old->prt_max;
new->reject_count = old->reject_count;
new->accepted = old->accepted;
old->prt_max = new_starts-1;
tor_assert(old->prt_min <= old->prt_max);
tor_assert(new->prt_min <= new->prt_max);
return new;
}
/* XXXX Nick says I'm going to hell for this. If he feels charitably towards
* my immortal soul, he can clean it up himself. */
#define AT(x) ((policy_summary_item_t*)smartlist_get(summary, x))
#define REJECT_CUTOFF_COUNT (1<<25)
/** Split an exit policy summary so that prt_min and prt_max
* fall at exactly the start and end of an item respectively.
*/
static int
policy_summary_split(smartlist_t *summary,
uint16_t prt_min, uint16_t prt_max)
{
int start_at_index;
int i = 0;
while (AT(i)->prt_max < prt_min)
i++;
if (AT(i)->prt_min != prt_min) {
policy_summary_item_t* new_item;
new_item = policy_summary_item_split(AT(i), prt_min);
smartlist_insert(summary, i+1, new_item);
i++;
}
start_at_index = i;
while (AT(i)->prt_max < prt_max)
i++;
if (AT(i)->prt_max != prt_max) {
policy_summary_item_t* new_item;
new_item = policy_summary_item_split(AT(i), prt_max+1);
smartlist_insert(summary, i+1, new_item);
}
return start_at_index;
}
/** Mark port ranges as accepted if they are below the reject_count */
static void
policy_summary_accept(smartlist_t *summary,
uint16_t prt_min, uint16_t prt_max)
{
int i = policy_summary_split(summary, prt_min, prt_max);
while (i < smartlist_len(summary) &&
AT(i)->prt_max <= prt_max) {
if (!AT(i)->accepted &&
AT(i)->reject_count <= REJECT_CUTOFF_COUNT)
AT(i)->accepted = 1;
i++;
}
tor_assert(i < smartlist_len(summary) || prt_max==65535);
}
/** Count the number of addresses in a network with prefixlen maskbits
* against the given portrange. */
static void
policy_summary_reject(smartlist_t *summary,
maskbits_t maskbits,
uint16_t prt_min, uint16_t prt_max)
{
int i = policy_summary_split(summary, prt_min, prt_max);
/* XXX: ipv4 specific */
uint64_t count = (U64_LITERAL(1) << (32-maskbits));
while (i < smartlist_len(summary) &&
AT(i)->prt_max <= prt_max) {
AT(i)->reject_count += count;
i++;
}
tor_assert(i < smartlist_len(summary) || prt_max==65535);
}
/** Add a single exit policy item to our summary:
* If it is an accept ignore it unless it is for all IP addresses
* ("*"), i.e. it's prefixlen/maskbits is 0, else call
* policy_summary_accept().
* If it's a reject ignore it if it is about one of the private
* networks, else call policy_summary_reject().
*/
static void
policy_summary_add_item(smartlist_t *summary, addr_policy_t *p)
{
if (p->policy_type == ADDR_POLICY_ACCEPT) {
if (p->maskbits == 0) {
policy_summary_accept(summary, p->prt_min, p->prt_max);
}
} else if (p->policy_type == ADDR_POLICY_REJECT) {
int is_private = 0;
int i;
for (i = 0; private_nets[i]; ++i) {
tor_addr_t addr;
maskbits_t maskbits;
if (tor_addr_parse_mask_ports(private_nets[i], 0, &addr,
&maskbits, NULL, NULL)<0) {
tor_assert(0);
}
if (tor_addr_compare(&p->addr, &addr, CMP_EXACT) == 0 &&
p->maskbits == maskbits) {
is_private = 1;
break;
}
}
if (!is_private) {
policy_summary_reject(summary, p->maskbits, p->prt_min, p->prt_max);
}
} else
tor_assert(0);
}
/** Create a string representing a summary for an exit policy.
2009-05-27 23:55:51 +02:00
* The summary will either be an "accept" plus a comma-separated list of port
* ranges or a "reject" plus port-ranges, depending on which is shorter.
*
* If no exits are allowed at all then "reject 1-65535" is returned. If no
* ports are blocked instead of "reject " we return "accept 1-65535". (These
* are an exception to the shorter-representation-wins rule).
*/
char *
policy_summarize(smartlist_t *policy, sa_family_t family)
{
smartlist_t *summary = policy_summary_create();
smartlist_t *accepts, *rejects;
int i, last, start_prt;
size_t accepts_len, rejects_len;
char *accepts_str = NULL, *rejects_str = NULL, *shorter_str, *result;
const char *prefix;
tor_assert(policy);
/* Create the summary list */
SMARTLIST_FOREACH_BEGIN(policy, addr_policy_t *, p) {
sa_family_t f = tor_addr_family(&p->addr);
if (f != AF_INET && f != AF_INET6) {
log_warn(LD_BUG, "Weird family when summarizing address policy");
}
if (f != family)
continue;
/* XXXX-ipv6 More family work is needed */
policy_summary_add_item(summary, p);
} SMARTLIST_FOREACH_END(p);
/* Now create two lists of strings, one for accepted and one
* for rejected ports. We take care to merge ranges so that
* we avoid getting stuff like "1-4,5-9,10", instead we want
* "1-10"
*/
i = 0;
start_prt = 1;
accepts = smartlist_new();
rejects = smartlist_new();
while (1) {
last = i == smartlist_len(summary)-1;
if (last ||
AT(i)->accepted != AT(i+1)->accepted) {
char buf[POLICY_BUF_LEN];
if (start_prt == AT(i)->prt_max)
tor_snprintf(buf, sizeof(buf), "%d", start_prt);
else
tor_snprintf(buf, sizeof(buf), "%d-%d", start_prt, AT(i)->prt_max);
if (AT(i)->accepted)
smartlist_add(accepts, tor_strdup(buf));
else
smartlist_add(rejects, tor_strdup(buf));
if (last)
break;
start_prt = AT(i+1)->prt_min;
};
i++;
};
/* Figure out which of the two stringlists will be shorter and use
* that to build the result
*/
if (smartlist_len(accepts) == 0) { /* no exits at all */
result = tor_strdup("reject 1-65535");
goto cleanup;
}
if (smartlist_len(rejects) == 0) { /* no rejects at all */
result = tor_strdup("accept 1-65535");
goto cleanup;
}
accepts_str = smartlist_join_strings(accepts, ",", 0, &accepts_len);
rejects_str = smartlist_join_strings(rejects, ",", 0, &rejects_len);
if (rejects_len > MAX_EXITPOLICY_SUMMARY_LEN-strlen("reject")-1 &&
accepts_len > MAX_EXITPOLICY_SUMMARY_LEN-strlen("accept")-1) {
char *c;
shorter_str = accepts_str;
prefix = "accept";
c = shorter_str + (MAX_EXITPOLICY_SUMMARY_LEN-strlen(prefix)-1);
while (*c != ',' && c >= shorter_str)
c--;
tor_assert(c >= shorter_str);
tor_assert(*c == ',');
*c = '\0';
} else if (rejects_len < accepts_len) {
shorter_str = rejects_str;
prefix = "reject";
} else {
shorter_str = accepts_str;
prefix = "accept";
}
tor_asprintf(&result, "%s %s", prefix, shorter_str);
2010-08-16 00:29:27 +02:00
cleanup:
/* cleanup */
SMARTLIST_FOREACH(summary, policy_summary_item_t *, s, tor_free(s));
smartlist_free(summary);
tor_free(accepts_str);
SMARTLIST_FOREACH(accepts, char *, s, tor_free(s));
smartlist_free(accepts);
tor_free(rejects_str);
SMARTLIST_FOREACH(rejects, char *, s, tor_free(s));
smartlist_free(rejects);
return result;
}
/** Convert a summarized policy string into a short_policy_t. Return NULL
* if the string is not well-formed. */
short_policy_t *
parse_short_policy(const char *summary)
{
const char *orig_summary = summary;
short_policy_t *result;
int is_accept;
int n_entries;
short_policy_entry_t entries[MAX_EXITPOLICY_SUMMARY_LEN]; /* overkill */
const char *next;
if (!strcmpstart(summary, "accept ")) {
is_accept = 1;
summary += strlen("accept ");
} else if (!strcmpstart(summary, "reject ")) {
is_accept = 0;
summary += strlen("reject ");
} else {
log_fn(LOG_PROTOCOL_WARN, LD_DIR, "Unrecognized policy summary keyword");
return NULL;
}
n_entries = 0;
for ( ; *summary; summary = next) {
const char *comma = strchr(summary, ',');
unsigned low, high;
char dummy;
char ent_buf[32];
size_t len;
next = comma ? comma+1 : strchr(summary, '\0');
len = comma ? (size_t)(comma - summary) : strlen(summary);
if (n_entries == MAX_EXITPOLICY_SUMMARY_LEN) {
log_fn(LOG_PROTOCOL_WARN, LD_DIR, "Impossibly long policy summary %s",
escaped(orig_summary));
return NULL;
}
if (! TOR_ISDIGIT(*summary) || len > (sizeof(ent_buf)-1)) {
/* unrecognized entry format. skip it. */
continue;
}
if (len < 1) {
/* empty; skip it. */
/* XXX This happens to be unreachable, since if len==0, then *summary is
* ',' or '\0', and the TOR_ISDIGIT test above would have failed. */
continue;
}
memcpy(ent_buf, summary, len);
ent_buf[len] = '\0';
if (tor_sscanf(ent_buf, "%u-%u%c", &low, &high, &dummy) == 2) {
if (low<1 || low>65535 || high<1 || high>65535 || low>high) {
2010-10-14 17:54:45 +02:00
log_fn(LOG_PROTOCOL_WARN, LD_DIR,
"Found bad entry in policy summary %s", escaped(orig_summary));
return NULL;
}
} else if (tor_sscanf(ent_buf, "%u%c", &low, &dummy) == 1) {
if (low<1 || low>65535) {
2010-10-14 17:54:45 +02:00
log_fn(LOG_PROTOCOL_WARN, LD_DIR,
"Found bad entry in policy summary %s", escaped(orig_summary));
return NULL;
}
high = low;
} else {
log_fn(LOG_PROTOCOL_WARN, LD_DIR,"Found bad entry in policy summary %s",
escaped(orig_summary));
return NULL;
}
entries[n_entries].min_port = low;
entries[n_entries].max_port = high;
n_entries++;
}
if (n_entries == 0) {
log_fn(LOG_PROTOCOL_WARN, LD_DIR,
"Found no port-range entries in summary %s", escaped(orig_summary));
return NULL;
}
{
size_t size = STRUCT_OFFSET(short_policy_t, entries) +
sizeof(short_policy_entry_t)*(n_entries);
result = tor_malloc_zero(size);
tor_assert( (char*)&result->entries[n_entries-1] < ((char*)result)+size);
}
result->is_accept = is_accept;
result->n_entries = n_entries;
memcpy(result->entries, entries, sizeof(short_policy_entry_t)*n_entries);
return result;
}
2012-10-22 23:09:43 +02:00
/** Write <b>policy</b> back out into a string. Used only for unit tests
* currently. */
char *
2012-10-22 23:09:43 +02:00
write_short_policy(const short_policy_t *policy)
{
int i;
char *answer;
smartlist_t *sl = smartlist_new();
smartlist_add_asprintf(sl, "%s", policy->is_accept ? "accept " : "reject ");
for (i=0; i < policy->n_entries; i++) {
2012-10-22 23:09:43 +02:00
const short_policy_entry_t *e = &policy->entries[i];
if (e->min_port == e->max_port) {
smartlist_add_asprintf(sl, "%d", e->min_port);
} else {
smartlist_add_asprintf(sl, "%d-%d", e->min_port, e->max_port);
}
if (i < policy->n_entries-1)
smartlist_add(sl, tor_strdup(","));
}
answer = smartlist_join_strings(sl, "", 0, NULL);
SMARTLIST_FOREACH(sl, char *, a, tor_free(a));
smartlist_free(sl);
return answer;
}
/** Release all storage held in <b>policy</b>. */
void
short_policy_free(short_policy_t *policy)
{
tor_free(policy);
}
/** See whether the <b>addr</b>:<b>port</b> address is likely to be accepted
* or rejected by the summarized policy <b>policy</b>. Return values are as
* for compare_tor_addr_to_addr_policy. Unlike the regular addr_policy
* functions, requires the <b>port</b> be specified. */
addr_policy_result_t
compare_tor_addr_to_short_policy(const tor_addr_t *addr, uint16_t port,
const short_policy_t *policy)
{
int i;
int found_match = 0;
int accept;
tor_assert(port != 0);
if (addr && tor_addr_is_null(addr))
addr = NULL; /* Unspec means 'no address at all,' in this context. */
if (addr && get_options()->ClientRejectInternalAddresses &&
(tor_addr_is_internal(addr, 0) || tor_addr_is_loopback(addr)))
return ADDR_POLICY_REJECTED;
for (i=0; i < policy->n_entries; ++i) {
const short_policy_entry_t *e = &policy->entries[i];
if (e->min_port <= port && port <= e->max_port) {
found_match = 1;
break;
}
}
if (found_match)
accept = policy->is_accept;
else
accept = ! policy->is_accept;
/* ???? are these right? -NM */
/* We should be sure not to return ADDR_POLICY_ACCEPTED in the accept
* case here, because it would cause clients to believe that the node
* allows exit enclaving. Trying it anyway would open up a cool attack
* where the node refuses due to exitpolicy, the client reacts in
* surprise by rewriting the node's exitpolicy to reject *:*, and then
* an adversary targets users by causing them to attempt such connections
* to 98% of the exits.
*
* Once microdescriptors can handle addresses in special cases (e.g. if
* we ever solve ticket 1774), we can provide certainty here. -RD */
if (accept)
return ADDR_POLICY_PROBABLY_ACCEPTED;
else
return ADDR_POLICY_REJECTED;
}
/** Return true iff <b>policy</b> seems reject all ports */
int
short_policy_is_reject_star(const short_policy_t *policy)
{
/* This doesn't need to be as much on the lookout as policy_is_reject_star,
2010-10-14 17:54:45 +02:00
* since policy summaries are from the consensus or from consensus
* microdescs.
*/
tor_assert(policy);
/* Check for an exact match of "reject 1-65535". */
return (policy->is_accept == 0 && policy->n_entries == 1 &&
policy->entries[0].min_port == 1 &&
policy->entries[0].max_port == 65535);
}
2012-12-03 19:33:43 +01:00
/** Decide whether addr:port is probably or definitely accepted or rejected by
Initial conversion to use node_t throughout our codebase. A node_t is an abstraction over routerstatus_t, routerinfo_t, and microdesc_t. It should try to present a consistent interface to all of them. There should be a node_t for a server whenever there is * A routerinfo_t for it in the routerlist * A routerstatus_t in the current_consensus. (note that a microdesc_t alone isn't enough to make a node_t exist, since microdescriptors aren't usable on their own.) There are three ways to get a node_t right now: looking it up by ID, looking it up by nickname, and iterating over the whole list of microdescriptors. All (or nearly all) functions that are supposed to return "a router" -- especially those used in building connections and circuits -- should return a node_t, not a routerinfo_t or a routerstatus_t. A node_t should hold all the *mutable* flags about a node. This patch moves the is_foo flags from routerinfo_t into node_t. The flags in routerstatus_t remain, but they get set from the consensus and should not change. Some other highlights of this patch are: * Looking up routerinfo and routerstatus by nickname is now unified and based on the "look up a node by nickname" function. This tries to look only at the values from current consensus, and not get confused by the routerinfo_t->is_named flag, which could get set for other weird reasons. This changes the behavior of how authorities (when acting as clients) deal with nodes that have been listed by nickname. * I tried not to artificially increase the size of the diff here by moving functions around. As a result, some functions that now operate on nodes are now in the wrong file -- they should get moved to nodelist.c once this refactoring settles down. This moving should happen as part of a patch that moves functions AND NOTHING ELSE. * Some old code is now left around inside #if 0/1 blocks, and should get removed once I've verified that I don't want it sitting around to see how we used to do things. There are still some unimplemented functions: these are flagged with "UNIMPLEMENTED_NODELIST()." I'll work on filling in the implementation here, piece by piece. I wish this patch could have been smaller, but there did not seem to be any piece of it that was independent from the rest. Moving flags forces many functions that once returned routerinfo_t * to return node_t *, which forces their friends to change, and so on.
2010-09-29 21:00:41 +02:00
* <b>node</b>. See compare_tor_addr_to_addr_policy for details on addr/port
* interpretation. */
addr_policy_result_t
compare_tor_addr_to_node_policy(const tor_addr_t *addr, uint16_t port,
const node_t *node)
{
if (node->rejects_all)
return ADDR_POLICY_REJECTED;
if (addr && tor_addr_family(addr) == AF_INET6) {
const short_policy_t *p = NULL;
if (node->ri)
p = node->ri->ipv6_exit_policy;
else if (node->md)
p = node->md->ipv6_exit_policy;
if (p)
return compare_tor_addr_to_short_policy(addr, port, p);
else
return ADDR_POLICY_REJECTED;
}
if (node->ri) {
return compare_tor_addr_to_addr_policy(addr, port, node->ri->exit_policy);
} else if (node->md) {
if (node->md->exit_policy == NULL)
return ADDR_POLICY_REJECTED;
else
return compare_tor_addr_to_short_policy(addr, port,
node->md->exit_policy);
} else {
return ADDR_POLICY_PROBABLY_REJECTED;
}
Initial conversion to use node_t throughout our codebase. A node_t is an abstraction over routerstatus_t, routerinfo_t, and microdesc_t. It should try to present a consistent interface to all of them. There should be a node_t for a server whenever there is * A routerinfo_t for it in the routerlist * A routerstatus_t in the current_consensus. (note that a microdesc_t alone isn't enough to make a node_t exist, since microdescriptors aren't usable on their own.) There are three ways to get a node_t right now: looking it up by ID, looking it up by nickname, and iterating over the whole list of microdescriptors. All (or nearly all) functions that are supposed to return "a router" -- especially those used in building connections and circuits -- should return a node_t, not a routerinfo_t or a routerstatus_t. A node_t should hold all the *mutable* flags about a node. This patch moves the is_foo flags from routerinfo_t into node_t. The flags in routerstatus_t remain, but they get set from the consensus and should not change. Some other highlights of this patch are: * Looking up routerinfo and routerstatus by nickname is now unified and based on the "look up a node by nickname" function. This tries to look only at the values from current consensus, and not get confused by the routerinfo_t->is_named flag, which could get set for other weird reasons. This changes the behavior of how authorities (when acting as clients) deal with nodes that have been listed by nickname. * I tried not to artificially increase the size of the diff here by moving functions around. As a result, some functions that now operate on nodes are now in the wrong file -- they should get moved to nodelist.c once this refactoring settles down. This moving should happen as part of a patch that moves functions AND NOTHING ELSE. * Some old code is now left around inside #if 0/1 blocks, and should get removed once I've verified that I don't want it sitting around to see how we used to do things. There are still some unimplemented functions: these are flagged with "UNIMPLEMENTED_NODELIST()." I'll work on filling in the implementation here, piece by piece. I wish this patch could have been smaller, but there did not seem to be any piece of it that was independent from the rest. Moving flags forces many functions that once returned routerinfo_t * to return node_t *, which forces their friends to change, and so on.
2010-09-29 21:00:41 +02:00
}
/**
* Given <b>policy_list</b>, a list of addr_policy_t, produce a string
* representation of the list.
* If <b>include_ipv4</b> is true, include IPv4 entries.
* If <b>include_ipv6</b> is true, include IPv6 entries.
*/
char *
policy_dump_to_string(const smartlist_t *policy_list,
int include_ipv4,
int include_ipv6)
{
smartlist_t *policy_string_list;
char *policy_string = NULL;
policy_string_list = smartlist_new();
SMARTLIST_FOREACH_BEGIN(policy_list, addr_policy_t *, tmpe) {
char *pbuf;
int bytes_written_to_pbuf;
if ((tor_addr_family(&tmpe->addr) == AF_INET6) && (!include_ipv6)) {
continue; /* Don't include IPv6 parts of address policy */
}
if ((tor_addr_family(&tmpe->addr) == AF_INET) && (!include_ipv4)) {
continue; /* Don't include IPv4 parts of address policy */
}
pbuf = tor_malloc(POLICY_BUF_LEN);
bytes_written_to_pbuf = policy_write_item(pbuf,POLICY_BUF_LEN, tmpe, 1);
if (bytes_written_to_pbuf < 0) {
log_warn(LD_BUG, "policy_dump_to_string ran out of room!");
tor_free(pbuf);
goto done;
}
smartlist_add(policy_string_list,pbuf);
} SMARTLIST_FOREACH_END(tmpe);
policy_string = smartlist_join_strings(policy_string_list, "\n", 0, NULL);
2015-11-20 16:52:56 +01:00
done:
SMARTLIST_FOREACH(policy_string_list, char *, str, tor_free(str));
smartlist_free(policy_string_list);
return policy_string;
}
/** Implementation for GETINFO control command: knows the answer for questions
* about "exit-policy/..." */
int
getinfo_helper_policies(control_connection_t *conn,
const char *question, char **answer,
const char **errmsg)
{
(void) conn;
(void) errmsg;
if (!strcmp(question, "exit-policy/default")) {
*answer = tor_strdup(DEFAULT_EXIT_POLICY);
} else if (!strcmp(question, "exit-policy/reject-private/default")) {
smartlist_t *private_policy_strings;
const char **priv = private_nets;
private_policy_strings = smartlist_new();
while (*priv != NULL) {
/* IPv6 addresses are in "[]" and contain ":",
* IPv4 addresses are not in "[]" and contain "." */
smartlist_add_asprintf(private_policy_strings, "reject %s:*", *priv);
priv++;
}
*answer = smartlist_join_strings(private_policy_strings,
",", 0, NULL);
SMARTLIST_FOREACH(private_policy_strings, char *, str, tor_free(str));
smartlist_free(private_policy_strings);
} else if (!strcmp(question, "exit-policy/reject-private/relay")) {
const or_options_t *options = get_options();
const routerinfo_t *me = router_get_my_routerinfo();
if (!me) {
*errmsg = "router_get_my_routerinfo returned NULL";
return -1;
}
if (!options->ExitPolicyRejectPrivate) {
*answer = tor_strdup("");
return 0;
}
smartlist_t *private_policy_list = smartlist_new();
smartlist_t *configured_addresses = smartlist_new();
/* Copy the configured addresses into the tor_addr_t* list */
policies_copy_ipv4h_to_smartlist(configured_addresses, me->addr);
policies_copy_addr_to_smartlist(configured_addresses, &me->ipv6_addr);
policies_copy_outbound_addresses_to_smartlist(configured_addresses,
options);
policies_parse_exit_policy_reject_private(
&private_policy_list,
options->IPv6Exit,
configured_addresses,
1, 1);
*answer = policy_dump_to_string(private_policy_list, 1, 1);
addr_policy_list_free(private_policy_list);
SMARTLIST_FOREACH(configured_addresses, tor_addr_t *, a, tor_free(a));
smartlist_free(configured_addresses);
} else if (!strcmpstart(question, "exit-policy/")) {
const routerinfo_t *me = router_get_my_routerinfo();
int include_ipv4 = 0;
int include_ipv6 = 0;
if (!strcmp(question, "exit-policy/ipv4")) {
include_ipv4 = 1;
} else if (!strcmp(question, "exit-policy/ipv6")) {
include_ipv6 = 1;
} else if (!strcmp(question, "exit-policy/full")) {
include_ipv4 = include_ipv6 = 1;
} else {
return 0; /* No such key. */
}
if (!me) {
*errmsg = "router_get_my_routerinfo returned NULL";
return -1;
}
*answer = router_dump_exit_policy_to_string(me,include_ipv4,include_ipv6);
}
return 0;
}
2007-05-25 21:41:31 +02:00
/** Release all storage held by <b>p</b>. */
void
addr_policy_list_free(smartlist_t *lst)
{
if (!lst)
return;
SMARTLIST_FOREACH(lst, addr_policy_t *, policy, addr_policy_free(policy));
smartlist_free(lst);
}
/** Release all storage held by <b>p</b>. */
void
addr_policy_free(addr_policy_t *p)
{
if (!p)
return;
if (--p->refcnt <= 0) {
if (p->is_canonical) {
policy_map_ent_t search, *found;
search.policy = p;
found = HT_REMOVE(policy_map, &policy_root, &search);
if (found) {
tor_assert(p == found->policy);
tor_free(found);
}
}
tor_free(p);
}
}
/** Release all storage held by policy variables. */
void
policies_free_all(void)
{
addr_policy_list_free(reachable_or_addr_policy);
reachable_or_addr_policy = NULL;
addr_policy_list_free(reachable_dir_addr_policy);
reachable_dir_addr_policy = NULL;
addr_policy_list_free(socks_policy);
socks_policy = NULL;
addr_policy_list_free(dir_policy);
dir_policy = NULL;
addr_policy_list_free(authdir_reject_policy);
authdir_reject_policy = NULL;
addr_policy_list_free(authdir_invalid_policy);
authdir_invalid_policy = NULL;
addr_policy_list_free(authdir_badexit_policy);
authdir_badexit_policy = NULL;
if (!HT_EMPTY(&policy_root)) {
policy_map_ent_t **ent;
int n = 0;
char buf[POLICY_BUF_LEN];
log_warn(LD_MM, "Still had %d address policies cached at shutdown.",
(int)HT_SIZE(&policy_root));
/* Note the first 10 cached policies to try to figure out where they
* might be coming from. */
HT_FOREACH(ent, policy_map, &policy_root) {
if (++n > 10)
break;
if (policy_write_item(buf, sizeof(buf), (*ent)->policy, 0) >= 0)
log_warn(LD_MM," %d [%d]: %s", n, (*ent)->policy->refcnt, buf);
}
}
HT_CLEAR(policy_map, &policy_root);
}