nihilist/tor
1
0
Fork 0
mirror of https://gitlab.torproject.org/tpo/core/tor.git synced 2024-11-11 13:43:47 +01:00
Code Issues Packages Projects Releases Wiki Activity
6fa99ab32f
tor/src/or/circuitbuild.c
Nick Mathewson 6aef89bda4 Remove compare_addr_to_node_policy 
Instead, use compare_tor_addr_to_node_policy everywhere.

One advantage of this is that compare_tor_addr_to_node_policy can
better distinguish 0.0.0.0 from "unknown", which caused a nasty bug
with microdesc users.
2011-07-15 13:04:12 -04:00

5168 lines
172 KiB
C
Raw Blame History

/* Copyright (c) 2001 Matej Pfajfar.
* Copyright (c) 2001-2004, Roger Dingledine.
* Copyright (c) 2004-2006, Roger Dingledine, Nick Mathewson.
* Copyright (c) 2007-2011, The Tor Project, Inc. */
/* See LICENSE for licensing information */
/**
* \file circuitbuild.c
* \brief The actual details of building circuits.
**/
#define CIRCUIT_PRIVATE
#include "or.h"
#include "circuitbuild.h"
#include "circuitlist.h"
#include "circuituse.h"
#include "config.h"
#include "connection.h"
#include "connection_edge.h"
#include "connection_or.h"
#include "control.h"
#include "directory.h"
#include "main.h"
#include "networkstatus.h"
#include "nodelist.h"
#include "onion.h"
#include "policies.h"
#include "relay.h"
#include "rephist.h"
#include "router.h"
#include "routerlist.h"
#include "routerparse.h"
#include "crypto.h"
#undef log
#include <math.h>
#ifndef MIN
#define MIN(a,b) ((a)<(b)?(a):(b))
#endif
#define CBT_BIN_TO_MS(bin) ((bin)*CBT_BIN_WIDTH + (CBT_BIN_WIDTH/2))
/********* START VARIABLES **********/
/** Global list of circuit build times */
// XXXX023: Add this as a member for entry_guard_t instead of global?
// Then we could do per-guard statistics, as guards are likely to
// vary in their own latency. The downside of this is that guards
// can change frequently, so we'd be building a lot more circuits
// most likely.
/* XXXX023 Make this static; add accessor functions. */
circuit_build_times_t circ_times;
/** A global list of all circuits at this hop. */
extern circuit_t *global_circuitlist;
/** An entry_guard_t represents our information about a chosen long-term
* first hop, known as a "helper" node in the literature. We can't just
* use a node_t, since we want to remember these even when we
* don't have any directory info. */
typedef struct {
char nickname[MAX_NICKNAME_LEN+1];
char identity[DIGEST_LEN];
time_t chosen_on_date; /**< Approximately when was this guard added?
* "0" if we don't know. */
char *chosen_by_version; /**< What tor version added this guard? NULL
* if we don't know. */
unsigned int made_contact : 1; /**< 0 if we have never connected to this
* router, 1 if we have. */
unsigned int can_retry : 1; /**< Should we retry connecting to this entry,
* in spite of having it marked as unreachable?*/
time_t bad_since; /**< 0 if this guard is currently usable, or the time at
* which it was observed to become (according to the
* directory or the user configuration) unusable. */
time_t unreachable_since; /**< 0 if we can connect to this guard, or the
* time at which we first noticed we couldn't
* connect to it. */
time_t last_attempted; /**< 0 if we can connect to this guard, or the time
* at which we last failed to connect to it. */
} entry_guard_t;
/** Information about a configured bridge. Currently this just matches the
* ones in the torrc file, but one day we may be able to learn about new
* bridges on our own, and remember them in the state file. */
typedef struct {
/** Address of the bridge. */
tor_addr_t addr;
/** TLS port for the bridge. */
uint16_t port;
/** Boolean: We are re-parsing our bridge list, and we are going to remove
* this one if we don't find it in the list of configured bridges. */
unsigned marked_for_removal : 1;
/** Expected identity digest, or all zero bytes if we don't know what the
* digest should be. */
char identity[DIGEST_LEN];
/** Name of pluggable transport protocol taken from its config line. */
char *transport_name;
/** When should we next try to fetch a descriptor for this bridge? */
download_status_t fetch_status;
} bridge_info_t;
/** A list of our chosen entry guards. */
static smartlist_t *entry_guards = NULL;
/** A value of 1 means that the entry_guards list has changed
* and those changes need to be flushed to disk. */
static int entry_guards_dirty = 0;
/** If set, we're running the unit tests: we should avoid clobbering
* our state file or accessing get_options() or get_or_state() */
static int unit_tests = 0;
/********* END VARIABLES ************/
static int circuit_deliver_create_cell(circuit_t *circ,
uint8_t cell_type, const char *payload);
static int onion_pick_cpath_exit(origin_circuit_t *circ, extend_info_t *exit);
static crypt_path_t *onion_next_hop_in_cpath(crypt_path_t *cpath);
static int onion_extend_cpath(origin_circuit_t *circ);
static int count_acceptable_nodes(smartlist_t *routers);
static int onion_append_hop(crypt_path_t **head_ptr, extend_info_t *choice);
static void entry_guards_changed(void);
static const transport_t *transport_get_by_name(const char *name);
static void transport_free(transport_t *transport);
static void bridge_free(bridge_info_t *bridge);
/**
* This function decides if CBT learning should be disabled. It returns
* true if one or more of the following four conditions are met:
*
* 1. If the cbtdisabled consensus parameter is set.
* 2. If the torrc option LearnCircuitBuildTimeout is false.
* 3. If we are a directory authority
* 4. If we fail to write circuit build time history to our state file.
*/
static int
circuit_build_times_disabled(void)
{
if (unit_tests) {
return 0;
} else {
int consensus_disabled = networkstatus_get_param(NULL, "cbtdisabled",
0, 0, 1);
int config_disabled = !get_options()->LearnCircuitBuildTimeout;
int dirauth_disabled = get_options()->AuthoritativeDir;
int state_disabled = did_last_state_file_write_fail() ? 1 : 0;
if (consensus_disabled || config_disabled || dirauth_disabled ||
state_disabled) {
log_info(LD_CIRC,
"CircuitBuildTime learning is disabled. "
"Consensus=%d, Config=%d, AuthDir=%d, StateFile=%d",
consensus_disabled, config_disabled, dirauth_disabled,
state_disabled);
return 1;
} else {
return 0;
}
}
}
/**
* Retrieve and bounds-check the cbtmaxtimeouts consensus paramter.
*
* Effect: When this many timeouts happen in the last 'cbtrecentcount'
* circuit attempts, the client should discard all of its history and
* begin learning a fresh timeout value.
*/
static int32_t
circuit_build_times_max_timeouts(void)
{
return networkstatus_get_param(NULL, "cbtmaxtimeouts",
CBT_DEFAULT_MAX_RECENT_TIMEOUT_COUNT,
CBT_MIN_MAX_RECENT_TIMEOUT_COUNT,
CBT_MAX_MAX_RECENT_TIMEOUT_COUNT);
}
/**
* Retrieve and bounds-check the cbtnummodes consensus paramter.
*
* Effect: This value governs how many modes to use in the weighted
* average calculation of Pareto parameter Xm. A value of 3 introduces
* some bias (2-5% of CDF) under ideal conditions, but allows for better
* performance in the event that a client chooses guard nodes of radically
* different performance characteristics.
*/
static int32_t
circuit_build_times_default_num_xm_modes(void)
{
int32_t num = networkstatus_get_param(NULL, "cbtnummodes",
CBT_DEFAULT_NUM_XM_MODES,
CBT_MIN_NUM_XM_MODES,
CBT_MAX_NUM_XM_MODES);
return num;
}
/**
* Retrieve and bounds-check the cbtmincircs consensus paramter.
*
* Effect: This is the minimum number of circuits to build before
* computing a timeout.
*/
static int32_t
circuit_build_times_min_circs_to_observe(void)
{
int32_t num = networkstatus_get_param(NULL, "cbtmincircs",
CBT_DEFAULT_MIN_CIRCUITS_TO_OBSERVE,
CBT_MIN_MIN_CIRCUITS_TO_OBSERVE,
CBT_MAX_MIN_CIRCUITS_TO_OBSERVE);
return num;
}
/** Return true iff <b>cbt</b> has recorded enough build times that we
* want to start acting on the timeout it implies. */
int
circuit_build_times_enough_to_compute(circuit_build_times_t *cbt)
{
return cbt->total_build_times >= circuit_build_times_min_circs_to_observe();
}
/**
* Retrieve and bounds-check the cbtquantile consensus paramter.
*
* Effect: This is the position on the quantile curve to use to set the
* timeout value. It is a percent (10-99).
*/
double
circuit_build_times_quantile_cutoff(void)
{
int32_t num = networkstatus_get_param(NULL, "cbtquantile",
CBT_DEFAULT_QUANTILE_CUTOFF,
CBT_MIN_QUANTILE_CUTOFF,
CBT_MAX_QUANTILE_CUTOFF);
return num/100.0;
}
int
circuit_build_times_get_bw_scale(networkstatus_t *ns)
{
return networkstatus_get_param(ns, "bwweightscale",
BW_WEIGHT_SCALE,
BW_MIN_WEIGHT_SCALE,
BW_MAX_WEIGHT_SCALE);
}
/**
* Retrieve and bounds-check the cbtclosequantile consensus paramter.
*
* Effect: This is the position on the quantile curve to use to set the
* timeout value to use to actually close circuits. It is a percent
* (0-99).
*/
static double
circuit_build_times_close_quantile(void)
{
int32_t param;
/* Cast is safe - circuit_build_times_quantile_cutoff() is capped */
int32_t min = (int)tor_lround(100*circuit_build_times_quantile_cutoff());
param = networkstatus_get_param(NULL, "cbtclosequantile",
CBT_DEFAULT_CLOSE_QUANTILE,
CBT_MIN_CLOSE_QUANTILE,
CBT_MAX_CLOSE_QUANTILE);
if (param < min) {
log_warn(LD_DIR, "Consensus parameter cbtclosequantile is "
"too small, raising to %d", min);
param = min;
}
return param / 100.0;
}
/**
* Retrieve and bounds-check the cbttestfreq consensus paramter.
*
* Effect: Describes how often in seconds to build a test circuit to
* gather timeout values. Only applies if less than 'cbtmincircs'
* have been recorded.
*/
static int32_t
circuit_build_times_test_frequency(void)
{
int32_t num = networkstatus_get_param(NULL, "cbttestfreq",
CBT_DEFAULT_TEST_FREQUENCY,
CBT_MIN_TEST_FREQUENCY,
CBT_MAX_TEST_FREQUENCY);
return num;
}
/**
* Retrieve and bounds-check the cbtmintimeout consensus parameter.
*
* Effect: This is the minimum allowed timeout value in milliseconds.
* The minimum is to prevent rounding to 0 (we only check once
* per second).
*/
static int32_t
circuit_build_times_min_timeout(void)
{
int32_t num = networkstatus_get_param(NULL, "cbtmintimeout",
CBT_DEFAULT_TIMEOUT_MIN_VALUE,
CBT_MIN_TIMEOUT_MIN_VALUE,
CBT_MAX_TIMEOUT_MIN_VALUE);
return num;
}
/**
* Retrieve and bounds-check the cbtinitialtimeout consensus paramter.
*
* Effect: This is the timeout value to use before computing a timeout,
* in milliseconds.
*/
int32_t
circuit_build_times_initial_timeout(void)
{
int32_t min = circuit_build_times_min_timeout();
int32_t param = networkstatus_get_param(NULL, "cbtinitialtimeout",
CBT_DEFAULT_TIMEOUT_INITIAL_VALUE,
CBT_MIN_TIMEOUT_INITIAL_VALUE,
CBT_MAX_TIMEOUT_INITIAL_VALUE);
if (param < min) {
log_warn(LD_DIR, "Consensus parameter cbtinitialtimeout is too small, "
"raising to %d", min);
param = min;
}
return param;
}
/**
* Retrieve and bounds-check the cbtrecentcount consensus paramter.
*
* Effect: This is the number of circuit build times to keep track of
* for deciding if we hit cbtmaxtimeouts and need to reset our state
* and learn a new timeout.
*/
static int32_t
circuit_build_times_recent_circuit_count(networkstatus_t *ns)
{
return networkstatus_get_param(ns, "cbtrecentcount",
CBT_DEFAULT_RECENT_CIRCUITS,
CBT_MIN_RECENT_CIRCUITS,
CBT_MAX_RECENT_CIRCUITS);
}
/**
* This function is called when we get a consensus update.
*
* It checks to see if we have changed any consensus parameters
* that require reallocation or discard of previous stats.
*/
void
circuit_build_times_new_consensus_params(circuit_build_times_t *cbt,
networkstatus_t *ns)
{
int32_t num = circuit_build_times_recent_circuit_count(ns);
if (num > 0 && num != cbt->liveness.num_recent_circs) {
int8_t *recent_circs;
log_notice(LD_CIRC, "The Tor Directory Consensus has changed how many "
"circuits we must track to detect network failures from %d "
"to %d.", cbt->liveness.num_recent_circs, num);
tor_assert(cbt->liveness.timeouts_after_firsthop);
/*
* Technically this is a circular array that we are reallocating
* and memcopying. However, since it only consists of either 1s
* or 0s, and is only used in a statistical test to determine when
* we should discard our history after a sufficient number of 1's
* have been reached, it is fine if order is not preserved or
* elements are lost.
*
* cbtrecentcount should only be changing in cases of severe network
* distress anyway, so memory correctness here is paramount over
* doing acrobatics to preserve the array.
*/
recent_circs = tor_malloc_zero(sizeof(int8_t)*num);
memcpy(recent_circs, cbt->liveness.timeouts_after_firsthop,
sizeof(int8_t)*MIN(num, cbt->liveness.num_recent_circs));
// Adjust the index if it needs it.
if (num < cbt->liveness.num_recent_circs) {
cbt->liveness.after_firsthop_idx = MIN(num-1,
cbt->liveness.after_firsthop_idx);
}
tor_free(cbt->liveness.timeouts_after_firsthop);
cbt->liveness.timeouts_after_firsthop = recent_circs;
cbt->liveness.num_recent_circs = num;
}
}
/** Make a note that we're running unit tests (rather than running Tor
* itself), so we avoid clobbering our state file. */
void
circuitbuild_running_unit_tests(void)
{
unit_tests = 1;
}
/**
* Return the initial default or configured timeout in milliseconds
*/
static double
circuit_build_times_get_initial_timeout(void)
{
double timeout;
if (!unit_tests && get_options()->CircuitBuildTimeout) {
timeout = get_options()->CircuitBuildTimeout*1000;
if (timeout < circuit_build_times_min_timeout()) {
log_warn(LD_CIRC, "Config CircuitBuildTimeout too low. Setting to %ds",
circuit_build_times_min_timeout()/1000);
timeout = circuit_build_times_min_timeout();
}
} else {
timeout = circuit_build_times_initial_timeout();
}
return timeout;
}
/**
* Reset the build time state.
*
* Leave estimated parameters, timeout and network liveness intact
* for future use.
*/
void
circuit_build_times_reset(circuit_build_times_t *cbt)
{
memset(cbt->circuit_build_times, 0, sizeof(cbt->circuit_build_times));
cbt->total_build_times = 0;
cbt->build_times_idx = 0;
cbt->have_computed_timeout = 0;
}
/**
* Initialize the buildtimes structure for first use.
*
* Sets the initial timeout values based on either the config setting,
* the consensus param, or the default (CBT_DEFAULT_TIMEOUT_INITIAL_VALUE).
*/
void
circuit_build_times_init(circuit_build_times_t *cbt)
{
memset(cbt, 0, sizeof(*cbt));
cbt->liveness.num_recent_circs =
circuit_build_times_recent_circuit_count(NULL);
cbt->liveness.timeouts_after_firsthop = tor_malloc_zero(sizeof(int8_t)*
cbt->liveness.num_recent_circs);
cbt->close_ms = cbt->timeout_ms = circuit_build_times_get_initial_timeout();
control_event_buildtimeout_set(cbt, BUILDTIMEOUT_SET_EVENT_RESET);
}
#if 0
/**
* Rewind our build time history by n positions.
*/
static void
circuit_build_times_rewind_history(circuit_build_times_t *cbt, int n)
{
int i = 0;
cbt->build_times_idx -= n;
cbt->build_times_idx %= CBT_NCIRCUITS_TO_OBSERVE;
for (i = 0; i < n; i++) {
cbt->circuit_build_times[(i+cbt->build_times_idx)
%CBT_NCIRCUITS_TO_OBSERVE]=0;
}
if (cbt->total_build_times > n) {
cbt->total_build_times -= n;
} else {
cbt->total_build_times = 0;
}
log_info(LD_CIRC,
"Rewound history by %d places. Current index: %d. "
"Total: %d", n, cbt->build_times_idx, cbt->total_build_times);
}
#endif
/**
* Add a new build time value <b>time</b> to the set of build times. Time
* units are milliseconds.
*
* circuit_build_times <b>cbt</b> is a circular array, so loop around when
* array is full.
*/
int
circuit_build_times_add_time(circuit_build_times_t *cbt, build_time_t time)
{
if (time <= 0 || time > CBT_BUILD_TIME_MAX) {
log_warn(LD_BUG, "Circuit build time is too large (%u)."
"This is probably a bug.", time);
tor_fragile_assert();
return -1;
}
log_debug(LD_CIRC, "Adding circuit build time %u", time);
cbt->circuit_build_times[cbt->build_times_idx] = time;
cbt->build_times_idx = (cbt->build_times_idx + 1) % CBT_NCIRCUITS_TO_OBSERVE;
if (cbt->total_build_times < CBT_NCIRCUITS_TO_OBSERVE)
cbt->total_build_times++;
if ((cbt->total_build_times % CBT_SAVE_STATE_EVERY) == 0) {
/* Save state every n circuit builds */
if (!unit_tests && !get_options()->AvoidDiskWrites)
or_state_mark_dirty(get_or_state(), 0);
}
return 0;
}
/**
* Return maximum circuit build time
*/
static build_time_t
circuit_build_times_max(circuit_build_times_t *cbt)
{
int i = 0;
build_time_t max_build_time = 0;
for (i = 0; i < CBT_NCIRCUITS_TO_OBSERVE; i++) {
if (cbt->circuit_build_times[i] > max_build_time
&& cbt->circuit_build_times[i] != CBT_BUILD_ABANDONED)
max_build_time = cbt->circuit_build_times[i];
}
return max_build_time;
}
#if 0
/** Return minimum circuit build time */
build_time_t
circuit_build_times_min(circuit_build_times_t *cbt)
{
int i = 0;
build_time_t min_build_time = CBT_BUILD_TIME_MAX;
for (i = 0; i < CBT_NCIRCUITS_TO_OBSERVE; i++) {
if (cbt->circuit_build_times[i] && /* 0 <-> uninitialized */
cbt->circuit_build_times[i] < min_build_time)
min_build_time = cbt->circuit_build_times[i];
}
if (min_build_time == CBT_BUILD_TIME_MAX) {
log_warn(LD_CIRC, "No build times less than CBT_BUILD_TIME_MAX!");
}
return min_build_time;
}
#endif
/**
* Calculate and return a histogram for the set of build times.
*
* Returns an allocated array of histrogram bins representing
* the frequency of index*CBT_BIN_WIDTH millisecond
* build times. Also outputs the number of bins in nbins.
*
* The return value must be freed by the caller.
*/
static uint32_t *
circuit_build_times_create_histogram(circuit_build_times_t *cbt,
build_time_t *nbins)
{
uint32_t *histogram;
build_time_t max_build_time = circuit_build_times_max(cbt);
int i, c;
*nbins = 1 + (max_build_time / CBT_BIN_WIDTH);
histogram = tor_malloc_zero(*nbins * sizeof(build_time_t));
// calculate histogram
for (i = 0; i < CBT_NCIRCUITS_TO_OBSERVE; i++) {
if (cbt->circuit_build_times[i] == 0
|| cbt->circuit_build_times[i] == CBT_BUILD_ABANDONED)
continue; /* 0 <-> uninitialized */
c = (cbt->circuit_build_times[i] / CBT_BIN_WIDTH);
histogram[c]++;
}
return histogram;
}
/**
* Return the Pareto start-of-curve parameter Xm.
*
* Because we are not a true Pareto curve, we compute this as the
* weighted average of the N most frequent build time bins. N is either
* 1 if we don't have enough circuit build time data collected, or
* determined by the consensus parameter cbtnummodes (default 3).
*/
static build_time_t
circuit_build_times_get_xm(circuit_build_times_t *cbt)
{
build_time_t i, nbins;
build_time_t *nth_max_bin;
int32_t bin_counts=0;
build_time_t ret = 0;
uint32_t *histogram = circuit_build_times_create_histogram(cbt, &nbins);
int n=0;
int num_modes = circuit_build_times_default_num_xm_modes();
tor_assert(nbins > 0);
tor_assert(num_modes > 0);
// Only use one mode if < 1000 buildtimes. Not enough data
// for multiple.
if (cbt->total_build_times < CBT_NCIRCUITS_TO_OBSERVE)
num_modes = 1;
nth_max_bin = (build_time_t*)tor_malloc_zero(num_modes*sizeof(build_time_t));
/* Determine the N most common build times */
for (i = 0; i < nbins; i++) {
if (histogram[i] >= histogram[nth_max_bin[0]]) {
nth_max_bin[0] = i;
}
for (n = 1; n < num_modes; n++) {
if (histogram[i] >= histogram[nth_max_bin[n]] &&
(!histogram[nth_max_bin[n-1]]
|| histogram[i] < histogram[nth_max_bin[n-1]])) {
nth_max_bin[n] = i;
}
}
}
for (n = 0; n < num_modes; n++) {
bin_counts += histogram[nth_max_bin[n]];
ret += CBT_BIN_TO_MS(nth_max_bin[n])*histogram[nth_max_bin[n]];
log_info(LD_CIRC, "Xm mode #%d: %u %u", n, CBT_BIN_TO_MS(nth_max_bin[n]),
histogram[nth_max_bin[n]]);
}
/* The following assert is safe, because we don't get called when we
* haven't observed at least CBT_MIN_MIN_CIRCUITS_TO_OBSERVE circuits. */
tor_assert(bin_counts > 0);
ret /= bin_counts;
tor_free(histogram);
tor_free(nth_max_bin);
return ret;
}
/**
* Output a histogram of current circuit build times to
* the or_state_t state structure.
*/
void
circuit_build_times_update_state(circuit_build_times_t *cbt,
or_state_t *state)
{
uint32_t *histogram;
build_time_t i = 0;
build_time_t nbins = 0;
config_line_t **next, *line;
histogram = circuit_build_times_create_histogram(cbt, &nbins);
// write to state
config_free_lines(state->BuildtimeHistogram);
next = &state->BuildtimeHistogram;
*next = NULL;
state->TotalBuildTimes = cbt->total_build_times;
state->CircuitBuildAbandonedCount = 0;
for (i = 0; i < CBT_NCIRCUITS_TO_OBSERVE; i++) {
if (cbt->circuit_build_times[i] == CBT_BUILD_ABANDONED)
state->CircuitBuildAbandonedCount++;
}
for (i = 0; i < nbins; i++) {
// compress the histogram by skipping the blanks
if (histogram[i] == 0) continue;
*next = line = tor_malloc_zero(sizeof(config_line_t));
line->key = tor_strdup("CircuitBuildTimeBin");
line->value = tor_malloc(25);
tor_snprintf(line->value, 25, "%d %d",
CBT_BIN_TO_MS(i), histogram[i]);
next = &(line->next);
}
if (!unit_tests) {
if (!get_options()->AvoidDiskWrites)
or_state_mark_dirty(get_or_state(), 0);
}
tor_free(histogram);
}
/**
* Shuffle the build times array.
*
* Adapted from http://en.wikipedia.org/wiki/Fisher-Yates_shuffle
*/
static void
circuit_build_times_shuffle_and_store_array(circuit_build_times_t *cbt,
build_time_t *raw_times,
uint32_t num_times)
{
uint32_t n = num_times;
if (num_times > CBT_NCIRCUITS_TO_OBSERVE) {
log_notice(LD_CIRC, "The number of circuit times that this Tor version "
"uses to calculate build times is less than the number stored "
"in your state file. Decreasing the circuit time history from "
"%lu to %d.", (unsigned long)num_times,
CBT_NCIRCUITS_TO_OBSERVE);
}
if (n > INT_MAX-1) {
log_warn(LD_CIRC, "For some insane reasons, you had %lu circuit build "
"observations in your state file. That's far too many; probably "
"there's a bug here.", (unsigned long)n);
n = INT_MAX-1;
}
/* This code can only be run on a compact array */
while (n-- > 1) {
int k = crypto_rand_int(n + 1); /* 0 <= k <= n. */
build_time_t tmp = raw_times[k];
raw_times[k] = raw_times[n];
raw_times[n] = tmp;
}
/* Since the times are now shuffled, take a random CBT_NCIRCUITS_TO_OBSERVE
* subset (ie the first CBT_NCIRCUITS_TO_OBSERVE values) */
for (n = 0; n < MIN(num_times, CBT_NCIRCUITS_TO_OBSERVE); n++) {
circuit_build_times_add_time(cbt, raw_times[n]);
}
}
/**
* Filter old synthetic timeouts that were created before the
* new right-censored Pareto calculation was deployed.
*
* Once all clients before 0.2.1.13-alpha are gone, this code
* will be unused.
*/
static int
circuit_build_times_filter_timeouts(circuit_build_times_t *cbt)
{
int num_filtered=0, i=0;
double timeout_rate = 0;
build_time_t max_timeout = 0;
timeout_rate = circuit_build_times_timeout_rate(cbt);
max_timeout = (build_time_t)cbt->close_ms;
for (i = 0; i < CBT_NCIRCUITS_TO_OBSERVE; i++) {
if (cbt->circuit_build_times[i] > max_timeout) {
build_time_t replaced = cbt->circuit_build_times[i];
num_filtered++;
cbt->circuit_build_times[i] = CBT_BUILD_ABANDONED;
log_debug(LD_CIRC, "Replaced timeout %d with %d", replaced,
cbt->circuit_build_times[i]);
}
}
log_info(LD_CIRC,
"We had %d timeouts out of %d build times, "
"and filtered %d above the max of %u",
(int)(cbt->total_build_times*timeout_rate),
cbt->total_build_times, num_filtered, max_timeout);
return num_filtered;
}
/**
* Load histogram from <b>state</b>, shuffling the resulting array
* after we do so. Use this result to estimate parameters and
* calculate the timeout.
*
* Return -1 on error.
*/
int
circuit_build_times_parse_state(circuit_build_times_t *cbt,
or_state_t *state)
{
int tot_values = 0;
uint32_t loaded_cnt = 0, N = 0;
config_line_t *line;
unsigned int i;
build_time_t *loaded_times;
int err = 0;
circuit_build_times_init(cbt);
if (circuit_build_times_disabled()) {
return 0;
}
/* build_time_t 0 means uninitialized */
loaded_times = tor_malloc_zero(sizeof(build_time_t)*state->TotalBuildTimes);
for (line = state->BuildtimeHistogram; line; line = line->next) {
smartlist_t *args = smartlist_create();
smartlist_split_string(args, line->value, " ",
SPLIT_SKIP_SPACE|SPLIT_IGNORE_BLANK, 0);
if (smartlist_len(args) < 2) {
log_warn(LD_GENERAL, "Unable to parse circuit build times: "
"Too few arguments to CircuitBuildTime");
err = 1;
SMARTLIST_FOREACH(args, char*, cp, tor_free(cp));
smartlist_free(args);
break;
} else {
const char *ms_str = smartlist_get(args,0);
const char *count_str = smartlist_get(args,1);
uint32_t count, k;
build_time_t ms;
int ok;
ms = (build_time_t)tor_parse_ulong(ms_str, 0, 0,
CBT_BUILD_TIME_MAX, &ok, NULL);
if (!ok) {
log_warn(LD_GENERAL, "Unable to parse circuit build times: "
"Unparsable bin number");
err = 1;
SMARTLIST_FOREACH(args, char*, cp, tor_free(cp));
smartlist_free(args);
break;
}
count = (uint32_t)tor_parse_ulong(count_str, 0, 0,
UINT32_MAX, &ok, NULL);
if (!ok) {
log_warn(LD_GENERAL, "Unable to parse circuit build times: "
"Unparsable bin count");
err = 1;
SMARTLIST_FOREACH(args, char*, cp, tor_free(cp));
smartlist_free(args);
break;
}
if (loaded_cnt+count+state->CircuitBuildAbandonedCount
> state->TotalBuildTimes) {
log_warn(LD_CIRC,
"Too many build times in state file. "
"Stopping short before %d",
loaded_cnt+count);
SMARTLIST_FOREACH(args, char*, cp, tor_free(cp));
smartlist_free(args);
break;
}
for (k = 0; k < count; k++) {
loaded_times[loaded_cnt++] = ms;
}
N++;
SMARTLIST_FOREACH(args, char*, cp, tor_free(cp));
smartlist_free(args);
}
}
log_info(LD_CIRC,
"Adding %d timeouts.", state->CircuitBuildAbandonedCount);
for (i=0; i < state->CircuitBuildAbandonedCount; i++) {
loaded_times[loaded_cnt++] = CBT_BUILD_ABANDONED;
}
if (loaded_cnt != state->TotalBuildTimes) {
log_warn(LD_CIRC,
"Corrupt state file? Build times count mismatch. "
"Read %d times, but file says %d", loaded_cnt,
state->TotalBuildTimes);
err = 1;
circuit_build_times_reset(cbt);
goto done;
}
circuit_build_times_shuffle_and_store_array(cbt, loaded_times, loaded_cnt);
/* Verify that we didn't overwrite any indexes */
for (i=0; i < CBT_NCIRCUITS_TO_OBSERVE; i++) {
if (!cbt->circuit_build_times[i])
break;
tot_values++;
}
log_info(LD_CIRC,
"Loaded %d/%d values from %d lines in circuit time histogram",
tot_values, cbt->total_build_times, N);
if (cbt->total_build_times != tot_values
|| cbt->total_build_times > CBT_NCIRCUITS_TO_OBSERVE) {
log_warn(LD_CIRC,
"Corrupt state file? Shuffled build times mismatch. "
"Read %d times, but file says %d", tot_values,
state->TotalBuildTimes);
err = 1;
circuit_build_times_reset(cbt);
goto done;
}
circuit_build_times_set_timeout(cbt);
if (!state->CircuitBuildAbandonedCount && cbt->total_build_times) {
circuit_build_times_filter_timeouts(cbt);
}
done:
tor_free(loaded_times);
return err ? -1 : 0;
}
/**
* Estimates the Xm and Alpha parameters using
* http://en.wikipedia.org/wiki/Pareto_distribution#Parameter_estimation
*
* The notable difference is that we use mode instead of min to estimate Xm.
* This is because our distribution is frechet-like. We claim this is
* an acceptable approximation because we are only concerned with the
* accuracy of the CDF of the tail.
*/
int
circuit_build_times_update_alpha(circuit_build_times_t *cbt)
{
build_time_t *x=cbt->circuit_build_times;
double a = 0;
int n=0,i=0,abandoned_count=0;
build_time_t max_time=0;
/* http://en.wikipedia.org/wiki/Pareto_distribution#Parameter_estimation */
/* We sort of cheat here and make our samples slightly more pareto-like
* and less frechet-like. */
cbt->Xm = circuit_build_times_get_xm(cbt);
tor_assert(cbt->Xm > 0);
for (i=0; i< CBT_NCIRCUITS_TO_OBSERVE; i++) {
if (!x[i]) {
continue;
}
if (x[i] < cbt->Xm) {
a += tor_mathlog(cbt->Xm);
} else if (x[i] == CBT_BUILD_ABANDONED) {
abandoned_count++;
} else {
a += tor_mathlog(x[i]);
if (x[i] > max_time)
max_time = x[i];
}
n++;
}
/*
* We are erring and asserting here because this can only happen
* in codepaths other than startup. The startup state parsing code
* performs this same check, and resets state if it hits it. If we
* hit it at runtime, something serious has gone wrong.
*/
if (n!=cbt->total_build_times) {
log_err(LD_CIRC, "Discrepancy in build times count: %d vs %d", n,
cbt->total_build_times);
}
tor_assert(n==cbt->total_build_times);
if (max_time <= 0) {
/* This can happen if Xm is actually the *maximum* value in the set.
* It can also happen if we've abandoned every single circuit somehow.
* In either case, tell the caller not to compute a new build timeout. */
log_warn(LD_BUG,
"Could not determine largest build time (%d). "
"Xm is %dms and we've abandoned %d out of %d circuits.", max_time,
cbt->Xm, abandoned_count, n);
return 0;
}
a += abandoned_count*tor_mathlog(max_time);
a -= n*tor_mathlog(cbt->Xm);
// Estimator comes from Eq #4 in:
// "Bayesian estimation based on trimmed samples from Pareto populations"
// by Arturo J. Fernández. We are right-censored only.
a = (n-abandoned_count)/a;
cbt->alpha = a;
return 1;
}
/**
* This is the Pareto Quantile Function. It calculates the point x
* in the distribution such that F(x) = quantile (ie quantile*100%
* of the mass of the density function is below x on the curve).
*
* We use it to calculate the timeout and also to generate synthetic
* values of time for circuits that timeout before completion.
*
* See http://en.wikipedia.org/wiki/Quantile_function,
* http://en.wikipedia.org/wiki/Inverse_transform_sampling and
* http://en.wikipedia.org/wiki/Pareto_distribution#Generating_a_
* random_sample_from_Pareto_distribution
* That's right. I'll cite wikipedia all day long.
*
* Return value is in milliseconds.
*/
double
circuit_build_times_calculate_timeout(circuit_build_times_t *cbt,
double quantile)
{
double ret;
tor_assert(quantile >= 0);
tor_assert(1.0-quantile > 0);
tor_assert(cbt->Xm > 0);
ret = cbt->Xm/pow(1.0-quantile,1.0/cbt->alpha);
if (ret > INT32_MAX) {
ret = INT32_MAX;
}
tor_assert(ret > 0);
return ret;
}
/** Pareto CDF */
double
circuit_build_times_cdf(circuit_build_times_t *cbt, double x)
{
double ret;
tor_assert(cbt->Xm > 0);
ret = 1.0-pow(cbt->Xm/x,cbt->alpha);
tor_assert(0 <= ret && ret <= 1.0);
return ret;
}
/**
* Generate a synthetic time using our distribution parameters.
*
* The return value will be within the [q_lo, q_hi) quantile points
* on the CDF.
*/
build_time_t
circuit_build_times_generate_sample(circuit_build_times_t *cbt,
double q_lo, double q_hi)
{
double randval = crypto_rand_double();
build_time_t ret;
double u;
/* Generate between [q_lo, q_hi) */
/*XXXX This is what nextafter is supposed to be for; we should use it on the
* platforms that support it. */
q_hi -= 1.0/(INT32_MAX);
tor_assert(q_lo >= 0);
tor_assert(q_hi < 1);
tor_assert(q_lo < q_hi);
u = q_lo + (q_hi-q_lo)*randval;
tor_assert(0 <= u && u < 1.0);
/* circuit_build_times_calculate_timeout returns <= INT32_MAX */
ret = (build_time_t)
tor_lround(circuit_build_times_calculate_timeout(cbt, u));
tor_assert(ret > 0);
return ret;
}
/**
* Estimate an initial alpha parameter by solving the quantile
* function with a quantile point and a specific timeout value.
*/
void
circuit_build_times_initial_alpha(circuit_build_times_t *cbt,
double quantile, double timeout_ms)
{
// Q(u) = Xm/((1-u)^(1/a))
// Q(0.8) = Xm/((1-0.8))^(1/a)) = CircBuildTimeout
// CircBuildTimeout = Xm/((1-0.8))^(1/a))
// CircBuildTimeout = Xm*((1-0.8))^(-1/a))
// ln(CircBuildTimeout) = ln(Xm)+ln(((1-0.8)))*(-1/a)
// -ln(1-0.8)/(ln(CircBuildTimeout)-ln(Xm))=a
tor_assert(quantile >= 0);
tor_assert(cbt->Xm > 0);
cbt->alpha = tor_mathlog(1.0-quantile)/
(tor_mathlog(cbt->Xm)-tor_mathlog(timeout_ms));
tor_assert(cbt->alpha > 0);
}
/**
* Returns true if we need circuits to be built
*/
int
circuit_build_times_needs_circuits(circuit_build_times_t *cbt)
{
/* Return true if < MIN_CIRCUITS_TO_OBSERVE */
return !circuit_build_times_enough_to_compute(cbt);
}
/**
* Returns true if we should build a timeout test circuit
* right now.
*/
int
circuit_build_times_needs_circuits_now(circuit_build_times_t *cbt)
{
return circuit_build_times_needs_circuits(cbt) &&
approx_time()-cbt->last_circ_at > circuit_build_times_test_frequency();
}
/**
* Called to indicate that the network showed some signs of liveness,
* i.e. we received a cell.
*
* This is used by circuit_build_times_network_check_live() to decide
* if we should record the circuit build timeout or not.
*
* This function is called every time we receive a cell. Avoid
* syscalls, events, and other high-intensity work.
*/
void
circuit_build_times_network_is_live(circuit_build_times_t *cbt)
{
time_t now = approx_time();
if (cbt->liveness.nonlive_timeouts > 0) {
log_notice(LD_CIRC,
"Tor now sees network activity. Restoring circuit build "
"timeout recording. Network was down for %d seconds "
"during %d circuit attempts.",
(int)(now - cbt->liveness.network_last_live),
cbt->liveness.nonlive_timeouts);
}
cbt->liveness.network_last_live = now;
cbt->liveness.nonlive_timeouts = 0;
}
/**
* Called to indicate that we completed a circuit. Because this circuit
* succeeded, it doesn't count as a timeout-after-the-first-hop.
*
* This is used by circuit_build_times_network_check_changed() to determine
* if we had too many recent timeouts and need to reset our learned timeout
* to something higher.
*/
void
circuit_build_times_network_circ_success(circuit_build_times_t *cbt)
{
cbt->liveness.timeouts_after_firsthop[cbt->liveness.after_firsthop_idx] = 0;
cbt->liveness.after_firsthop_idx++;
cbt->liveness.after_firsthop_idx %= cbt->liveness.num_recent_circs;
}
/**
* A circuit just timed out. If it failed after the first hop, record it
* in our history for later deciding if the network speed has changed.
*
* This is used by circuit_build_times_network_check_changed() to determine
* if we had too many recent timeouts and need to reset our learned timeout
* to something higher.
*/
static void
circuit_build_times_network_timeout(circuit_build_times_t *cbt,
int did_onehop)
{
if (did_onehop) {
cbt->liveness.timeouts_after_firsthop[cbt->liveness.after_firsthop_idx]=1;
cbt->liveness.after_firsthop_idx++;
cbt->liveness.after_firsthop_idx %= cbt->liveness.num_recent_circs;
}
}
/**
* A circuit was just forcibly closed. If there has been no recent network
* activity at all, but this circuit was launched back when we thought the
* network was live, increment the number of "nonlive" circuit timeouts.
*
* This is used by circuit_build_times_network_check_live() to decide
* if we should record the circuit build timeout or not.
*/
static void
circuit_build_times_network_close(circuit_build_times_t *cbt,
int did_onehop, time_t start_time)
{
time_t now = time(NULL);
/*
* Check if this is a timeout that was for a circuit that spent its
* entire existence during a time where we have had no network activity.
*/
if (cbt->liveness.network_last_live < start_time) {
if (did_onehop) {
char last_live_buf[ISO_TIME_LEN+1];
char start_time_buf[ISO_TIME_LEN+1];
char now_buf[ISO_TIME_LEN+1];
format_local_iso_time(last_live_buf, cbt->liveness.network_last_live);
format_local_iso_time(start_time_buf, start_time);
format_local_iso_time(now_buf, now);
log_warn(LD_BUG,
"Circuit somehow completed a hop while the network was "
"not live. Network was last live at %s, but circuit launched "
"at %s. It's now %s.", last_live_buf, start_time_buf,
now_buf);
}
cbt->liveness.nonlive_timeouts++;
if (cbt->liveness.nonlive_timeouts == 1) {
log_notice(LD_CIRC,
"Tor has not observed any network activity for the past %d "
"seconds. Disabling circuit build timeout recording.",
(int)(now - cbt->liveness.network_last_live));
} else {
log_info(LD_CIRC,
"Got non-live timeout. Current count is: %d",
cbt->liveness.nonlive_timeouts);
}
}
}
/**
* When the network is not live, we do not record circuit build times.
*
* The network is considered not live if there has been at least one
* circuit build that began and ended (had its close_ms measurement
* period expire) since we last received a cell.
*
* Also has the side effect of rewinding the circuit time history
* in the case of recent liveness changes.
*/
int
circuit_build_times_network_check_live(circuit_build_times_t *cbt)
{
if (cbt->liveness.nonlive_timeouts > 0) {
return 0;
}
return 1;
}
/**
* Returns true if we have seen more than MAX_RECENT_TIMEOUT_COUNT of
* the past RECENT_CIRCUITS time out after the first hop. Used to detect
* if the network connection has changed significantly, and if so,
* resets our circuit build timeout to the default.
*
* Also resets the entire timeout history in this case and causes us
* to restart the process of building test circuits and estimating a
* new timeout.
*/
int
circuit_build_times_network_check_changed(circuit_build_times_t *cbt)
{
int total_build_times = cbt->total_build_times;
int timeout_count=0;
int i;
/* how many of our recent circuits made it to the first hop but then
* timed out? */
for (i = 0; i < cbt->liveness.num_recent_circs; i++) {
timeout_count += cbt->liveness.timeouts_after_firsthop[i];
}
/* If 80% of our recent circuits are timing out after the first hop,
* we need to re-estimate a new initial alpha and timeout. */
if (timeout_count < circuit_build_times_max_timeouts()) {
return 0;
}
circuit_build_times_reset(cbt);
memset(cbt->liveness.timeouts_after_firsthop, 0,
sizeof(*cbt->liveness.timeouts_after_firsthop)*
cbt->liveness.num_recent_circs);
cbt->liveness.after_firsthop_idx = 0;
/* Check to see if this has happened before. If so, double the timeout
* to give people on abysmally bad network connections a shot at access */
if (cbt->timeout_ms >= circuit_build_times_get_initial_timeout()) {
if (cbt->timeout_ms > INT32_MAX/2 || cbt->close_ms > INT32_MAX/2) {
log_warn(LD_CIRC, "Insanely large circuit build timeout value. "
"(timeout = %lfmsec, close = %lfmsec)",
cbt->timeout_ms, cbt->close_ms);
} else {
cbt->timeout_ms *= 2;
cbt->close_ms *= 2;
}
} else {
cbt->close_ms = cbt->timeout_ms
= circuit_build_times_get_initial_timeout();
}
control_event_buildtimeout_set(cbt, BUILDTIMEOUT_SET_EVENT_RESET);
log_notice(LD_CIRC,
"Your network connection speed appears to have changed. Resetting "
"timeout to %lds after %d timeouts and %d buildtimes.",
tor_lround(cbt->timeout_ms/1000), timeout_count,
total_build_times);
return 1;
}
/**
* Count the number of timeouts in a set of cbt data.
*/
double
circuit_build_times_timeout_rate(const circuit_build_times_t *cbt)
{
int i=0,timeouts=0;
for (i = 0; i < CBT_NCIRCUITS_TO_OBSERVE; i++) {
if (cbt->circuit_build_times[i] >= cbt->timeout_ms) {
timeouts++;
}
}
if (!cbt->total_build_times)
return 0;
return ((double)timeouts)/cbt->total_build_times;
}
/**
* Count the number of closed circuits in a set of cbt data.
*/
double
circuit_build_times_close_rate(const circuit_build_times_t *cbt)
{
int i=0,closed=0;
for (i = 0; i < CBT_NCIRCUITS_TO_OBSERVE; i++) {
if (cbt->circuit_build_times[i] == CBT_BUILD_ABANDONED) {
closed++;
}
}
if (!cbt->total_build_times)
return 0;
return ((double)closed)/cbt->total_build_times;
}
/**
* Store a timeout as a synthetic value.
*
* Returns true if the store was successful and we should possibly
* update our timeout estimate.
*/
int
circuit_build_times_count_close(circuit_build_times_t *cbt,
int did_onehop,
time_t start_time)
{
if (circuit_build_times_disabled()) {
cbt->close_ms = cbt->timeout_ms
= circuit_build_times_get_initial_timeout();
return 0;
}
/* Record this force-close to help determine if the network is dead */
circuit_build_times_network_close(cbt, did_onehop, start_time);
/* Only count timeouts if network is live.. */
if (!circuit_build_times_network_check_live(cbt)) {
return 0;
}
circuit_build_times_add_time(cbt, CBT_BUILD_ABANDONED);
return 1;
}
/**
* Update timeout counts to determine if we need to expire
* our build time history due to excessive timeouts.
*
* We do not record any actual time values at this stage;
* we are only interested in recording the fact that a timeout
* happened. We record the time values via
* circuit_build_times_count_close() and circuit_build_times_add_time().
*/
void
circuit_build_times_count_timeout(circuit_build_times_t *cbt,
int did_onehop)
{
if (circuit_build_times_disabled()) {
cbt->close_ms = cbt->timeout_ms
= circuit_build_times_get_initial_timeout();
return;
}
/* Register the fact that a timeout just occurred. */
circuit_build_times_network_timeout(cbt, did_onehop);
/* If there are a ton of timeouts, we should reset
* the circuit build timeout. */
circuit_build_times_network_check_changed(cbt);
}
/**
* Estimate a new timeout based on history and set our timeout
* variable accordingly.
*/
static int
circuit_build_times_set_timeout_worker(circuit_build_times_t *cbt)
{
build_time_t max_time;
if (!circuit_build_times_enough_to_compute(cbt))
return 0;
if (!circuit_build_times_update_alpha(cbt))
return 0;
cbt->timeout_ms = circuit_build_times_calculate_timeout(cbt,
circuit_build_times_quantile_cutoff());
cbt->close_ms = circuit_build_times_calculate_timeout(cbt,
circuit_build_times_close_quantile());
max_time = circuit_build_times_max(cbt);
/* Sometimes really fast guard nodes give us such a steep curve
* that this ends up being not that much greater than timeout_ms.
* Make it be at least 1 min to handle this case. */
cbt->close_ms = MAX(cbt->close_ms, circuit_build_times_initial_timeout());
if (cbt->timeout_ms > max_time) {
log_notice(LD_CIRC,
"Circuit build timeout of %dms is beyond the maximum build "
"time we have ever observed. Capping it to %dms.",
(int)cbt->timeout_ms, max_time);
cbt->timeout_ms = max_time;
}
if (max_time < INT32_MAX/2 && cbt->close_ms > 2*max_time) {
log_info(LD_CIRC,
"Circuit build measurement period of %dms is more than twice "
"the maximum build time we have ever observed. Capping it to "
"%dms.", (int)cbt->close_ms, 2*max_time);
cbt->close_ms = 2*max_time;
}
cbt->have_computed_timeout = 1;
return 1;
}
/**
* Exposed function to compute a new timeout. Dispatches events and
* also filters out extremely high timeout values.
*/
void
circuit_build_times_set_timeout(circuit_build_times_t *cbt)
{
long prev_timeout = tor_lround(cbt->timeout_ms/1000);
double timeout_rate;
if (!circuit_build_times_set_timeout_worker(cbt))
return;
if (cbt->timeout_ms < circuit_build_times_min_timeout()) {
log_warn(LD_CIRC, "Set buildtimeout to low value %lfms. Setting to %dms",
cbt->timeout_ms, circuit_build_times_min_timeout());
cbt->timeout_ms = circuit_build_times_min_timeout();
if (cbt->close_ms < cbt->timeout_ms) {
/* This shouldn't happen because of MAX() in timeout_worker above,
* but doing it just in case */
cbt->close_ms = circuit_build_times_initial_timeout();
}
}
control_event_buildtimeout_set(cbt, BUILDTIMEOUT_SET_EVENT_COMPUTED);
timeout_rate = circuit_build_times_timeout_rate(cbt);
if (prev_timeout > tor_lround(cbt->timeout_ms/1000)) {
log_notice(LD_CIRC,
"Based on %d circuit times, it looks like we don't need to "
"wait so long for circuits to finish. We will now assume a "
"circuit is too slow to use after waiting %ld seconds.",
cbt->total_build_times,
tor_lround(cbt->timeout_ms/1000));
log_info(LD_CIRC,
"Circuit timeout data: %lfms, %lfms, Xm: %d, a: %lf, r: %lf",
cbt->timeout_ms, cbt->close_ms, cbt->Xm, cbt->alpha,
timeout_rate);
} else if (prev_timeout < tor_lround(cbt->timeout_ms/1000)) {
log_notice(LD_CIRC,
"Based on %d circuit times, it looks like we need to wait "
"longer for circuits to finish. We will now assume a "
"circuit is too slow to use after waiting %ld seconds.",
cbt->total_build_times,
tor_lround(cbt->timeout_ms/1000));
log_info(LD_CIRC,
"Circuit timeout data: %lfms, %lfms, Xm: %d, a: %lf, r: %lf",
cbt->timeout_ms, cbt->close_ms, cbt->Xm, cbt->alpha,
timeout_rate);
} else {
log_info(LD_CIRC,
"Set circuit build timeout to %lds (%lfms, %lfms, Xm: %d, a: %lf,"
" r: %lf) based on %d circuit times",
tor_lround(cbt->timeout_ms/1000),
cbt->timeout_ms, cbt->close_ms, cbt->Xm, cbt->alpha, timeout_rate,
cbt->total_build_times);
}
}
/** Iterate over values of circ_id, starting from conn-\>next_circ_id,
* and with the high bit specified by conn-\>circ_id_type, until we get
* a circ_id that is not in use by any other circuit on that conn.
*
* Return it, or 0 if can't get a unique circ_id.
*/
static circid_t
get_unique_circ_id_by_conn(or_connection_t *conn)
{
circid_t test_circ_id;
circid_t attempts=0;
circid_t high_bit;
tor_assert(conn);
if (conn->circ_id_type == CIRC_ID_TYPE_NEITHER) {
log_warn(LD_BUG, "Trying to pick a circuit ID for a connection from "
"a client with no identity.");
return 0;
}
high_bit = (conn->circ_id_type == CIRC_ID_TYPE_HIGHER) ? 1<<15 : 0;
do {
/* Sequentially iterate over test_circ_id=1...1<<15-1 until we find a
* circID such that (high_bit|test_circ_id) is not already used. */
test_circ_id = conn->next_circ_id++;
if (test_circ_id == 0 || test_circ_id >= 1<<15) {
test_circ_id = 1;
conn->next_circ_id = 2;
}
if (++attempts > 1<<15) {
/* Make sure we don't loop forever if all circ_id's are used. This
* matters because it's an external DoS opportunity.
*/
log_warn(LD_CIRC,"No unused circ IDs. Failing.");
return 0;
}
test_circ_id |= high_bit;
} while (circuit_id_in_use_on_orconn(test_circ_id, conn));
return test_circ_id;
}
/** If <b>verbose</b> is false, allocate and return a comma-separated list of
* the currently built elements of <b>circ</b>. If <b>verbose</b> is true, also
* list information about link status in a more verbose format using spaces.
* If <b>verbose_names</b> is false, give nicknames for Named routers and hex
* digests for others; if <b>verbose_names</b> is true, use $DIGEST=Name style
* names.
*/
static char *
circuit_list_path_impl(origin_circuit_t *circ, int verbose, int verbose_names)
{
crypt_path_t *hop;
smartlist_t *elements;
const char *states[] = {"closed", "waiting for keys", "open"};
char *s;
elements = smartlist_create();
if (verbose) {
const char *nickname = build_state_get_exit_nickname(circ->build_state);
char *cp;
tor_asprintf(&cp, "%s%s circ (length %d%s%s):",
circ->build_state->is_internal ? "internal" : "exit",
circ->build_state->need_uptime ? " (high-uptime)" : "",
circ->build_state->desired_path_len,
circ->_base.state == CIRCUIT_STATE_OPEN ? "" : ", last hop ",
circ->_base.state == CIRCUIT_STATE_OPEN ? "" :
(nickname?nickname:"*unnamed*"));
smartlist_add(elements, cp);
}
hop = circ->cpath;
do {
char *elt;
const char *id;
const node_t *node;
if (!hop)
break;
if (!verbose && hop->state != CPATH_STATE_OPEN)
break;
if (!hop->extend_info)
break;
id = hop->extend_info->identity_digest;
if (verbose_names) {
elt = tor_malloc(MAX_VERBOSE_NICKNAME_LEN+1);
if ((node = node_get_by_id(id))) {
node_get_verbose_nickname(node, elt);
} else if (is_legal_nickname(hop->extend_info->nickname)) {
elt[0] = '$';
base16_encode(elt+1, HEX_DIGEST_LEN+1, id, DIGEST_LEN);
elt[HEX_DIGEST_LEN+1]= '~';
strlcpy(elt+HEX_DIGEST_LEN+2,
hop->extend_info->nickname, MAX_NICKNAME_LEN+1);
} else {
elt[0] = '$';
base16_encode(elt+1, HEX_DIGEST_LEN+1, id, DIGEST_LEN);
}
} else { /* ! verbose_names */
node = node_get_by_id(id);
if (node && node_is_named(node)) {
elt = tor_strdup(node_get_nickname(node));
} else {
elt = tor_malloc(HEX_DIGEST_LEN+2);
elt[0] = '$';
base16_encode(elt+1, HEX_DIGEST_LEN+1, id, DIGEST_LEN);
}
}
tor_assert(elt);
if (verbose) {
size_t len = strlen(elt)+2+strlen(states[hop->state])+1;
char *v = tor_malloc(len);
tor_assert(hop->state <= 2);
tor_snprintf(v,len,"%s(%s)",elt,states[hop->state]);
smartlist_add(elements, v);
tor_free(elt);
} else {
smartlist_add(elements, elt);
}
hop = hop->next;
} while (hop != circ->cpath);
s = smartlist_join_strings(elements, verbose?" ":",", 0, NULL);
SMARTLIST_FOREACH(elements, char*, cp, tor_free(cp));
smartlist_free(elements);
return s;
}
/** If <b>verbose</b> is false, allocate and return a comma-separated
* list of the currently built elements of <b>circ</b>. If
* <b>verbose</b> is true, also list information about link status in
* a more verbose format using spaces.
*/
char *
circuit_list_path(origin_circuit_t *circ, int verbose)
{
return circuit_list_path_impl(circ, verbose, 0);
}
/** Allocate and return a comma-separated list of the currently built elements
* of <b>circ</b>, giving each as a verbose nickname.
*/
char *
circuit_list_path_for_controller(origin_circuit_t *circ)
{
return circuit_list_path_impl(circ, 0, 1);
}
/** Log, at severity <b>severity</b>, the nicknames of each router in
* <b>circ</b>'s cpath. Also log the length of the cpath, and the intended
* exit point.
*/
void
circuit_log_path(int severity, unsigned int domain, origin_circuit_t *circ)
{
char *s = circuit_list_path(circ,1);
tor_log(severity,domain,"%s",s);
tor_free(s);
}
/** Tell the rep(utation)hist(ory) module about the status of the links
* in <b>circ</b>. Hops that have become OPEN are marked as successfully
* extended; the _first_ hop that isn't open (if any) is marked as
* unable to extend.
*/
/* XXXX Someday we should learn from OR circuits too. */
void
circuit_rep_hist_note_result(origin_circuit_t *circ)
{
crypt_path_t *hop;
const char *prev_digest = NULL;
hop = circ->cpath;
if (!hop) /* circuit hasn't started building yet. */
return;
if (server_mode(get_options())) {
const routerinfo_t *me = router_get_my_routerinfo();
if (!me)
return;
prev_digest = me->cache_info.identity_digest;
}
do {
const node_t *node = node_get_by_id(hop->extend_info->identity_digest);
if (node) { /* Why do we check this? We know the identity. -NM XXXX */
if (prev_digest) {
if (hop->state == CPATH_STATE_OPEN)
rep_hist_note_extend_succeeded(prev_digest, node->identity);
else {
rep_hist_note_extend_failed(prev_digest, node->identity);
break;
}
}
prev_digest = node->identity;
} else {
prev_digest = NULL;
}
hop=hop->next;
} while (hop!=circ->cpath);
}
/** Pick all the entries in our cpath. Stop and return 0 when we're
* happy, or return -1 if an error occurs. */
static int
onion_populate_cpath(origin_circuit_t *circ)
{
int r;
again:
r = onion_extend_cpath(circ);
if (r < 0) {
log_info(LD_CIRC,"Generating cpath hop failed.");
return -1;
}
if (r == 0)
goto again;
return 0; /* if r == 1 */
}
/** Create and return a new origin circuit. Initialize its purpose and
* build-state based on our arguments. The <b>flags</b> argument is a
* bitfield of CIRCLAUNCH_* flags. */
origin_circuit_t *
origin_circuit_init(uint8_t purpose, int flags)
{
/* sets circ->p_circ_id and circ->p_conn */
origin_circuit_t *circ = origin_circuit_new();
circuit_set_state(TO_CIRCUIT(circ), CIRCUIT_STATE_OR_WAIT);
circ->build_state = tor_malloc_zero(sizeof(cpath_build_state_t));
circ->build_state->onehop_tunnel =
((flags & CIRCLAUNCH_ONEHOP_TUNNEL) ? 1 : 0);
circ->build_state->need_uptime =
((flags & CIRCLAUNCH_NEED_UPTIME) ? 1 : 0);
circ->build_state->need_capacity =
((flags & CIRCLAUNCH_NEED_CAPACITY) ? 1 : 0);
circ->build_state->is_internal =
((flags & CIRCLAUNCH_IS_INTERNAL) ? 1 : 0);
circ->_base.purpose = purpose;
return circ;
}
/** Build a new circuit for <b>purpose</b>. If <b>exit</b>
* is defined, then use that as your exit router, else choose a suitable
* exit node.
*
* Also launch a connection to the first OR in the chosen path, if
* it's not open already.
*/
origin_circuit_t *
circuit_establish_circuit(uint8_t purpose, extend_info_t *exit, int flags)
{
origin_circuit_t *circ;
int err_reason = 0;
circ = origin_circuit_init(purpose, flags);
if (onion_pick_cpath_exit(circ, exit) < 0 ||
onion_populate_cpath(circ) < 0) {
circuit_mark_for_close(TO_CIRCUIT(circ), END_CIRC_REASON_NOPATH);
return NULL;
}
control_event_circuit_status(circ, CIRC_EVENT_LAUNCHED, 0);
if ((err_reason = circuit_handle_first_hop(circ)) < 0) {
circuit_mark_for_close(TO_CIRCUIT(circ), -err_reason);
return NULL;
}
return circ;
}
/** Start establishing the first hop of our circuit. Figure out what
* OR we should connect to, and if necessary start the connection to
* it. If we're already connected, then send the 'create' cell.
* Return 0 for ok, -reason if circ should be marked-for-close. */
int
circuit_handle_first_hop(origin_circuit_t *circ)
{
crypt_path_t *firsthop;
or_connection_t *n_conn;
int err_reason = 0;
const char *msg = NULL;
int should_launch = 0;
firsthop = onion_next_hop_in_cpath(circ->cpath);
tor_assert(firsthop);
tor_assert(firsthop->extend_info);
/* now see if we're already connected to the first OR in 'route' */
log_debug(LD_CIRC,"Looking for firsthop '%s:%u'",
fmt_addr(&firsthop->extend_info->addr),
firsthop->extend_info->port);
n_conn = connection_or_get_for_extend(firsthop->extend_info->identity_digest,
&firsthop->extend_info->addr,
&msg,
&should_launch);
if (!n_conn) {
/* not currently connected in a useful way. */
log_info(LD_CIRC, "Next router is %s: %s",
safe_str_client(extend_info_describe(firsthop->extend_info)),
msg?msg:"???");
circ->_base.n_hop = extend_info_dup(firsthop->extend_info);
if (should_launch) {
if (circ->build_state->onehop_tunnel)
control_event_bootstrap(BOOTSTRAP_STATUS_CONN_DIR, 0);
n_conn = connection_or_connect(&firsthop->extend_info->addr,
firsthop->extend_info->port,
firsthop->extend_info->identity_digest);
if (!n_conn) { /* connect failed, forget the whole thing */
log_info(LD_CIRC,"connect to firsthop failed. Closing.");
return -END_CIRC_REASON_CONNECTFAILED;
}
}
log_debug(LD_CIRC,"connecting in progress (or finished). Good.");
/* return success. The onion/circuit/etc will be taken care of
* automatically (may already have been) whenever n_conn reaches
* OR_CONN_STATE_OPEN.
*/
return 0;
} else { /* it's already open. use it. */
tor_assert(!circ->_base.n_hop);
circ->_base.n_conn = n_conn;
log_debug(LD_CIRC,"Conn open. Delivering first onion skin.");
if ((err_reason = circuit_send_next_onion_skin(circ)) < 0) {
log_info(LD_CIRC,"circuit_send_next_onion_skin failed.");
return err_reason;
}
}
return 0;
}
/** Find any circuits that are waiting on <b>or_conn</b> to become
* open and get them to send their create cells forward.
*
* Status is 1 if connect succeeded, or 0 if connect failed.
*/
void
circuit_n_conn_done(or_connection_t *or_conn, int status)
{
smartlist_t *pending_circs;
int err_reason = 0;
log_debug(LD_CIRC,"or_conn to %s/%s, status=%d",
or_conn->nickname ? or_conn->nickname : "NULL",
or_conn->_base.address, status);
pending_circs = smartlist_create();
circuit_get_all_pending_on_or_conn(pending_circs, or_conn);
SMARTLIST_FOREACH_BEGIN(pending_circs, circuit_t *, circ)
{
/* These checks are redundant wrt get_all_pending_on_or_conn, but I'm
* leaving them in in case it's possible for the status of a circuit to
* change as we're going down the list. */
if (circ->marked_for_close || circ->n_conn || !circ->n_hop ||
circ->state != CIRCUIT_STATE_OR_WAIT)
continue;
if (tor_digest_is_zero(circ->n_hop->identity_digest)) {
/* Look at addr/port. This is an unkeyed connection. */
if (!tor_addr_eq(&circ->n_hop->addr, &or_conn->_base.addr) ||
circ->n_hop->port != or_conn->_base.port)
continue;
} else {
/* We expected a key. See if it's the right one. */
if (tor_memneq(or_conn->identity_digest,
circ->n_hop->identity_digest, DIGEST_LEN))
continue;
}
if (!status) { /* or_conn failed; close circ */
log_info(LD_CIRC,"or_conn failed. Closing circ.");
circuit_mark_for_close(circ, END_CIRC_REASON_OR_CONN_CLOSED);
continue;
}
log_debug(LD_CIRC, "Found circ, sending create cell.");
/* circuit_deliver_create_cell will set n_circ_id and add us to
* orconn_circuid_circuit_map, so we don't need to call
* set_circid_orconn here. */
circ->n_conn = or_conn;
extend_info_free(circ->n_hop);
circ->n_hop = NULL;
if (CIRCUIT_IS_ORIGIN(circ)) {
if ((err_reason =
circuit_send_next_onion_skin(TO_ORIGIN_CIRCUIT(circ))) < 0) {
log_info(LD_CIRC,
"send_next_onion_skin failed; circuit marked for closing.");
circuit_mark_for_close(circ, -err_reason);
continue;
/* XXX could this be bad, eg if next_onion_skin failed because conn
* died? */
}
} else {
/* pull the create cell out of circ->onionskin, and send it */
tor_assert(circ->n_conn_onionskin);
if (circuit_deliver_create_cell(circ,CELL_CREATE,
circ->n_conn_onionskin)<0) {
circuit_mark_for_close(circ, END_CIRC_REASON_RESOURCELIMIT);
continue;
}
tor_free(circ->n_conn_onionskin);
circuit_set_state(circ, CIRCUIT_STATE_OPEN);
}
}
SMARTLIST_FOREACH_END(circ);
smartlist_free(pending_circs);
}
/** Find a new circid that isn't currently in use on the circ->n_conn
* for the outgoing
* circuit <b>circ</b>, and deliver a cell of type <b>cell_type</b>
* (either CELL_CREATE or CELL_CREATE_FAST) with payload <b>payload</b>
* to this circuit.
* Return -1 if we failed to find a suitable circid, else return 0.
*/
static int
circuit_deliver_create_cell(circuit_t *circ, uint8_t cell_type,
const char *payload)
{
cell_t cell;
circid_t id;
tor_assert(circ);
tor_assert(circ->n_conn);
tor_assert(payload);
tor_assert(cell_type == CELL_CREATE || cell_type == CELL_CREATE_FAST);
id = get_unique_circ_id_by_conn(circ->n_conn);
if (!id) {
log_warn(LD_CIRC,"failed to get unique circID.");
return -1;
}
log_debug(LD_CIRC,"Chosen circID %u.", id);
circuit_set_n_circid_orconn(circ, id, circ->n_conn);
memset(&cell, 0, sizeof(cell_t));
cell.command = cell_type;
cell.circ_id = circ->n_circ_id;
memcpy(cell.payload, payload, ONIONSKIN_CHALLENGE_LEN);
append_cell_to_circuit_queue(circ, circ->n_conn, &cell,
CELL_DIRECTION_OUT, 0);
if (CIRCUIT_IS_ORIGIN(circ)) {
/* mark it so it gets better rate limiting treatment. */
circ->n_conn->client_used = time(NULL);
}
return 0;
}
/** We've decided to start our reachability testing. If all
* is set, log this to the user. Return 1 if we did, or 0 if
* we chose not to log anything. */
int
inform_testing_reachability(void)
{
char dirbuf[128];
const routerinfo_t *me = router_get_my_routerinfo();
if (!me)
return 0;
control_event_server_status(LOG_NOTICE,
"CHECKING_REACHABILITY ORADDRESS=%s:%d",
me->address, me->or_port);
if (me->dir_port) {
tor_snprintf(dirbuf, sizeof(dirbuf), " and DirPort %s:%d",
me->address, me->dir_port);
control_event_server_status(LOG_NOTICE,
"CHECKING_REACHABILITY DIRADDRESS=%s:%d",
me->address, me->dir_port);
}
log_notice(LD_OR, "Now checking whether ORPort %s:%d%s %s reachable... "
"(this may take up to %d minutes -- look for log "
"messages indicating success)",
me->address, me->or_port,
me->dir_port ? dirbuf : "",
me->dir_port ? "are" : "is",
TIMEOUT_UNTIL_UNREACHABILITY_COMPLAINT/60);
return 1;
}
/** Return true iff we should send a create_fast cell to start building a given
* circuit */
static INLINE int
should_use_create_fast_for_circuit(origin_circuit_t *circ)
{
const or_options_t *options = get_options();
tor_assert(circ->cpath);
tor_assert(circ->cpath->extend_info);
if (!circ->cpath->extend_info->onion_key)
return 1; /* our hand is forced: only a create_fast will work. */
if (!options->FastFirstHopPK)
return 0; /* we prefer to avoid create_fast */
if (server_mode(options)) {
/* We're a server, and we know an onion key. We can choose.
* Prefer to blend in. */
return 0;
}
return 1;
}
/** Return true if <b>circ</b> is the type of circuit we want to count
* timeouts from. In particular, we want it to have not completed yet
* (already completing indicates we cannibalized it), and we want it to
* have exactly three hops.
*/
int
circuit_timeout_want_to_count_circ(origin_circuit_t *circ)
{
return !circ->has_opened
&& circ->build_state->desired_path_len == DEFAULT_ROUTE_LEN;
}
/** This is the backbone function for building circuits.
*
* If circ's first hop is closed, then we need to build a create
* cell and send it forward.
*
* Otherwise, we need to build a relay extend cell and send it
* forward.
*
* Return -reason if we want to tear down circ, else return 0.
*/
int
circuit_send_next_onion_skin(origin_circuit_t *circ)
{
crypt_path_t *hop;
const node_t *node;
char payload[2+4+DIGEST_LEN+ONIONSKIN_CHALLENGE_LEN];
char *onionskin;
size_t payload_len;
tor_assert(circ);
if (circ->cpath->state == CPATH_STATE_CLOSED) {
int fast;
uint8_t cell_type;
log_debug(LD_CIRC,"First skin; sending create cell.");
if (circ->build_state->onehop_tunnel)
control_event_bootstrap(BOOTSTRAP_STATUS_ONEHOP_CREATE, 0);
else
control_event_bootstrap(BOOTSTRAP_STATUS_CIRCUIT_CREATE, 0);
node = node_get_by_id(circ->_base.n_conn->identity_digest);
fast = should_use_create_fast_for_circuit(circ);
if (!fast) {
/* We are an OR and we know the right onion key: we should
* send an old slow create cell.
*/
cell_type = CELL_CREATE;
if (onion_skin_create(circ->cpath->extend_info->onion_key,
&(circ->cpath->dh_handshake_state),
payload) < 0) {
log_warn(LD_CIRC,"onion_skin_create (first hop) failed.");
return - END_CIRC_REASON_INTERNAL;
}
note_request("cell: create", 1);
} else {
/* We are not an OR, and we're building the first hop of a circuit to a
* new OR: we can be speedy and use CREATE_FAST to save an RSA operation
* and a DH operation. */
cell_type = CELL_CREATE_FAST;
memset(payload, 0, sizeof(payload));
crypto_rand((char*) circ->cpath->fast_handshake_state,
sizeof(circ->cpath->fast_handshake_state));
memcpy(payload, circ->cpath->fast_handshake_state,
sizeof(circ->cpath->fast_handshake_state));
note_request("cell: create fast", 1);
}
if (circuit_deliver_create_cell(TO_CIRCUIT(circ), cell_type, payload) < 0)
return - END_CIRC_REASON_RESOURCELIMIT;
circ->cpath->state = CPATH_STATE_AWAITING_KEYS;
circuit_set_state(TO_CIRCUIT(circ), CIRCUIT_STATE_BUILDING);
log_info(LD_CIRC,"First hop: finished sending %s cell to '%s'",
fast ? "CREATE_FAST" : "CREATE",
node ? node_describe(node) : "<unnamed>");
} else {
tor_assert(circ->cpath->state == CPATH_STATE_OPEN);
tor_assert(circ->_base.state == CIRCUIT_STATE_BUILDING);
log_debug(LD_CIRC,"starting to send subsequent skin.");
hop = onion_next_hop_in_cpath(circ->cpath);
if (!hop) {
/* done building the circuit. whew. */
circuit_set_state(TO_CIRCUIT(circ), CIRCUIT_STATE_OPEN);
if (circuit_timeout_want_to_count_circ(circ)) {
struct timeval end;
long timediff;
tor_gettimeofday(&end);
timediff = tv_mdiff(&circ->_base.timestamp_created, &end);
/*
* If the circuit build time is much greater than we would have cut
* it off at, we probably had a suspend event along this codepath,
* and we should discard the value.
*/
if (timediff < 0 || timediff > 2*circ_times.close_ms+1000) {
log_notice(LD_CIRC, "Strange value for circuit build time: %ldmsec. "
"Assuming clock jump. Purpose %d (%s)", timediff,
circ->_base.purpose,
circuit_purpose_to_string(circ->_base.purpose));
} else if (!circuit_build_times_disabled()) {
/* Only count circuit times if the network is live */
if (circuit_build_times_network_check_live(&circ_times)) {
circuit_build_times_add_time(&circ_times, (build_time_t)timediff);
circuit_build_times_set_timeout(&circ_times);
}
if (circ->_base.purpose != CIRCUIT_PURPOSE_C_MEASURE_TIMEOUT) {
circuit_build_times_network_circ_success(&circ_times);
}
}
}
log_info(LD_CIRC,"circuit built!");
circuit_reset_failure_count(0);
if (circ->build_state->onehop_tunnel)
control_event_bootstrap(BOOTSTRAP_STATUS_REQUESTING_STATUS, 0);
if (!can_complete_circuit && !circ->build_state->onehop_tunnel) {
const or_options_t *options = get_options();
can_complete_circuit=1;
/* FFFF Log a count of known routers here */
log_notice(LD_GENERAL,
"Tor has successfully opened a circuit. "
"Looks like client functionality is working.");
control_event_bootstrap(BOOTSTRAP_STATUS_DONE, 0);
control_event_client_status(LOG_NOTICE, "CIRCUIT_ESTABLISHED");
clear_broken_connection_map(1);
if (server_mode(options) && !check_whether_orport_reachable()) {
inform_testing_reachability();
consider_testing_reachability(1, 1);
}
}
circuit_rep_hist_note_result(circ);
circuit_has_opened(circ); /* do other actions as necessary */
/* We're done with measurement circuits here. Just close them */
if (circ->_base.purpose == CIRCUIT_PURPOSE_C_MEASURE_TIMEOUT)
circuit_mark_for_close(TO_CIRCUIT(circ), END_CIRC_REASON_FINISHED);
return 0;
}
if (tor_addr_family(&hop->extend_info->addr) != AF_INET) {
log_warn(LD_BUG, "Trying to extend to a non-IPv4 address.");
return - END_CIRC_REASON_INTERNAL;
}
set_uint32(payload, tor_addr_to_ipv4n(&hop->extend_info->addr));
set_uint16(payload+4, htons(hop->extend_info->port));
onionskin = payload+2+4;
memcpy(payload+2+4+ONIONSKIN_CHALLENGE_LEN,
hop->extend_info->identity_digest, DIGEST_LEN);
payload_len = 2+4+ONIONSKIN_CHALLENGE_LEN+DIGEST_LEN;
if (onion_skin_create(hop->extend_info->onion_key,
&(hop->dh_handshake_state), onionskin) < 0) {
log_warn(LD_CIRC,"onion_skin_create failed.");
return - END_CIRC_REASON_INTERNAL;
}
log_info(LD_CIRC,"Sending extend relay cell.");
note_request("cell: extend", 1);
/* send it to hop->prev, because it will transfer
* it to a create cell and then send to hop */
if (relay_send_command_from_edge(0, TO_CIRCUIT(circ),
RELAY_COMMAND_EXTEND,
payload, payload_len, hop->prev) < 0)
return 0; /* circuit is closed */
hop->state = CPATH_STATE_AWAITING_KEYS;
}
return 0;
}
/** Our clock just jumped by <b>seconds_elapsed</b>. Assume
* something has also gone wrong with our network: notify the user,
* and abandon all not-yet-used circuits. */
void
circuit_note_clock_jumped(int seconds_elapsed)
{
int severity = server_mode(get_options()) ? LOG_WARN : LOG_NOTICE;
tor_log(severity, LD_GENERAL, "Your system clock just jumped %d seconds %s; "
"assuming established circuits no longer work.",
seconds_elapsed >=0 ? seconds_elapsed : -seconds_elapsed,
seconds_elapsed >=0 ? "forward" : "backward");
control_event_general_status(LOG_WARN, "CLOCK_JUMPED TIME=%d",
seconds_elapsed);
can_complete_circuit=0; /* so it'll log when it works again */
control_event_client_status(severity, "CIRCUIT_NOT_ESTABLISHED REASON=%s",
"CLOCK_JUMPED");
circuit_mark_all_unused_circs();
circuit_expire_all_dirty_circs();
}
/** Take the 'extend' <b>cell</b>, pull out addr/port plus the onion
* skin and identity digest for the next hop. If we're already connected,
* pass the onion skin to the next hop using a create cell; otherwise
* launch a new OR connection, and <b>circ</b> will notice when the
* connection succeeds or fails.
*
* Return -1 if we want to warn and tear down the circuit, else return 0.
*/
int
circuit_extend(cell_t *cell, circuit_t *circ)
{
or_connection_t *n_conn;
relay_header_t rh;
char *onionskin;
char *id_digest=NULL;
uint32_t n_addr32;
uint16_t n_port;
tor_addr_t n_addr;
const char *msg = NULL;
int should_launch = 0;
if (circ->n_conn) {
log_fn(LOG_PROTOCOL_WARN, LD_PROTOCOL,
"n_conn already set. Bug/attack. Closing.");
return -1;
}
if (circ->n_hop) {
log_fn(LOG_PROTOCOL_WARN, LD_PROTOCOL,
"conn to next hop already launched. Bug/attack. Closing.");
return -1;
}
if (!server_mode(get_options())) {
log_fn(LOG_PROTOCOL_WARN, LD_PROTOCOL,
"Got an extend cell, but running as a client. Closing.");
return -1;
}
relay_header_unpack(&rh, cell->payload);
if (rh.length < 4+2+ONIONSKIN_CHALLENGE_LEN+DIGEST_LEN) {
log_fn(LOG_PROTOCOL_WARN, LD_PROTOCOL,
"Wrong length %d on extend cell. Closing circuit.",
rh.length);
return -1;
}
n_addr32 = ntohl(get_uint32(cell->payload+RELAY_HEADER_SIZE));
n_port = ntohs(get_uint16(cell->payload+RELAY_HEADER_SIZE+4));
onionskin = (char*) cell->payload+RELAY_HEADER_SIZE+4+2;
id_digest = (char*) cell->payload+RELAY_HEADER_SIZE+4+2+
ONIONSKIN_CHALLENGE_LEN;
tor_addr_from_ipv4h(&n_addr, n_addr32);
if (!n_port || !n_addr32) {
log_fn(LOG_PROTOCOL_WARN, LD_PROTOCOL,
"Client asked me to extend to zero destination port or addr.");
return -1;
}
/* Check if they asked us for 0000..0000. We support using
* an empty fingerprint for the first hop (e.g. for a bridge relay),
* but we don't want to let people send us extend cells for empty
* fingerprints -- a) because it opens the user up to a mitm attack,
* and b) because it lets an attacker force the relay to hold open a
* new TLS connection for each extend request. */
if (tor_digest_is_zero(id_digest)) {
log_fn(LOG_PROTOCOL_WARN, LD_PROTOCOL,
"Client asked me to extend without specifying an id_digest.");
return -1;
}
/* Next, check if we're being asked to connect to the hop that the
* extend cell came from. There isn't any reason for that, and it can
* assist circular-path attacks. */
if (tor_memeq(id_digest, TO_OR_CIRCUIT(circ)->p_conn->identity_digest,
DIGEST_LEN)) {
log_fn(LOG_PROTOCOL_WARN, LD_PROTOCOL,
"Client asked me to extend back to the previous hop.");
return -1;
}
n_conn = connection_or_get_for_extend(id_digest,
&n_addr,
&msg,
&should_launch);
if (!n_conn) {
log_debug(LD_CIRC|LD_OR,"Next router (%s:%d): %s",
fmt_addr(&n_addr), (int)n_port, msg?msg:"????");
circ->n_hop = extend_info_alloc(NULL /*nickname*/,
id_digest,
NULL /*onion_key*/,
&n_addr, n_port);
circ->n_conn_onionskin = tor_malloc(ONIONSKIN_CHALLENGE_LEN);
memcpy(circ->n_conn_onionskin, onionskin, ONIONSKIN_CHALLENGE_LEN);
circuit_set_state(circ, CIRCUIT_STATE_OR_WAIT);
if (should_launch) {
/* we should try to open a connection */
n_conn = connection_or_connect(&n_addr, n_port, id_digest);
if (!n_conn) {
log_info(LD_CIRC,"Launching n_conn failed. Closing circuit.");
circuit_mark_for_close(circ, END_CIRC_REASON_CONNECTFAILED);
return 0;
}
log_debug(LD_CIRC,"connecting in progress (or finished). Good.");
}
/* return success. The onion/circuit/etc will be taken care of
* automatically (may already have been) whenever n_conn reaches
* OR_CONN_STATE_OPEN.
*/
return 0;
}
tor_assert(!circ->n_hop); /* Connection is already established. */
circ->n_conn = n_conn;
log_debug(LD_CIRC,"n_conn is %s:%u",
n_conn->_base.address,n_conn->_base.port);
if (circuit_deliver_create_cell(circ, CELL_CREATE, onionskin) < 0)
return -1;
return 0;
}
/** Initialize cpath-\>{f|b}_{crypto|digest} from the key material in
* key_data. key_data must contain CPATH_KEY_MATERIAL bytes, which are
* used as follows:
* - 20 to initialize f_digest
* - 20 to initialize b_digest
* - 16 to key f_crypto
* - 16 to key b_crypto
*
* (If 'reverse' is true, then f_XX and b_XX are swapped.)
*/
int
circuit_init_cpath_crypto(crypt_path_t *cpath, const char *key_data,
int reverse)
{
crypto_digest_env_t *tmp_digest;
crypto_cipher_env_t *tmp_crypto;
tor_assert(cpath);
tor_assert(key_data);
tor_assert(!(cpath->f_crypto || cpath->b_crypto ||
cpath->f_digest || cpath->b_digest));
cpath->f_digest = crypto_new_digest_env();
crypto_digest_add_bytes(cpath->f_digest, key_data, DIGEST_LEN);
cpath->b_digest = crypto_new_digest_env();
crypto_digest_add_bytes(cpath->b_digest, key_data+DIGEST_LEN, DIGEST_LEN);
if (!(cpath->f_crypto =
crypto_create_init_cipher(key_data+(2*DIGEST_LEN),1))) {
log_warn(LD_BUG,"Forward cipher initialization failed.");
return -1;
}
if (!(cpath->b_crypto =
crypto_create_init_cipher(key_data+(2*DIGEST_LEN)+CIPHER_KEY_LEN,0))) {
log_warn(LD_BUG,"Backward cipher initialization failed.");
return -1;
}
if (reverse) {
tmp_digest = cpath->f_digest;
cpath->f_digest = cpath->b_digest;
cpath->b_digest = tmp_digest;
tmp_crypto = cpath->f_crypto;
cpath->f_crypto = cpath->b_crypto;
cpath->b_crypto = tmp_crypto;
}
return 0;
}
/** A created or extended cell came back to us on the circuit, and it included
* <b>reply</b> as its body. (If <b>reply_type</b> is CELL_CREATED, the body
* contains (the second DH key, plus KH). If <b>reply_type</b> is
* CELL_CREATED_FAST, the body contains a secret y and a hash H(x|y).)
*
* Calculate the appropriate keys and digests, make sure KH is
* correct, and initialize this hop of the cpath.
*
* Return - reason if we want to mark circ for close, else return 0.
*/
int
circuit_finish_handshake(origin_circuit_t *circ, uint8_t reply_type,
const uint8_t *reply)
{
char keys[CPATH_KEY_MATERIAL_LEN];
crypt_path_t *hop;
if (circ->cpath->state == CPATH_STATE_AWAITING_KEYS)
hop = circ->cpath;
else {
hop = onion_next_hop_in_cpath(circ->cpath);
if (!hop) { /* got an extended when we're all done? */
log_warn(LD_PROTOCOL,"got extended when circ already built? Closing.");
return - END_CIRC_REASON_TORPROTOCOL;
}
}
tor_assert(hop->state == CPATH_STATE_AWAITING_KEYS);
if (reply_type == CELL_CREATED && hop->dh_handshake_state) {
if (onion_skin_client_handshake(hop->dh_handshake_state, (char*)reply,keys,
DIGEST_LEN*2+CIPHER_KEY_LEN*2) < 0) {
log_warn(LD_CIRC,"onion_skin_client_handshake failed.");
return -END_CIRC_REASON_TORPROTOCOL;
}
/* Remember hash of g^xy */
memcpy(hop->handshake_digest, reply+DH_KEY_LEN, DIGEST_LEN);
} else if (reply_type == CELL_CREATED_FAST && !hop->dh_handshake_state) {
if (fast_client_handshake(hop->fast_handshake_state, reply,
(uint8_t*)keys,
DIGEST_LEN*2+CIPHER_KEY_LEN*2) < 0) {
log_warn(LD_CIRC,"fast_client_handshake failed.");
return -END_CIRC_REASON_TORPROTOCOL;
}
memcpy(hop->handshake_digest, reply+DIGEST_LEN, DIGEST_LEN);
} else {
log_warn(LD_PROTOCOL,"CREATED cell type did not match CREATE cell type.");
return -END_CIRC_REASON_TORPROTOCOL;
}
crypto_dh_free(hop->dh_handshake_state); /* don't need it anymore */
hop->dh_handshake_state = NULL;
memset(hop->fast_handshake_state, 0, sizeof(hop->fast_handshake_state));
if (circuit_init_cpath_crypto(hop, keys, 0)<0) {
return -END_CIRC_REASON_TORPROTOCOL;
}
hop->state = CPATH_STATE_OPEN;
log_info(LD_CIRC,"Finished building %scircuit hop:",
(reply_type == CELL_CREATED_FAST) ? "fast " : "");
circuit_log_path(LOG_INFO,LD_CIRC,circ);
control_event_circuit_status(circ, CIRC_EVENT_EXTENDED, 0);
return 0;
}
/** We received a relay truncated cell on circ.
*
* Since we don't ask for truncates currently, getting a truncated
* means that a connection broke or an extend failed. For now,
* just give up: for circ to close, and return 0.
*/
int
circuit_truncated(origin_circuit_t *circ, crypt_path_t *layer)
{
// crypt_path_t *victim;
// connection_t *stream;
tor_assert(circ);
tor_assert(layer);
/* XXX Since we don't ask for truncates currently, getting a truncated
* means that a connection broke or an extend failed. For now,
* just give up.
*/
circuit_mark_for_close(TO_CIRCUIT(circ),
END_CIRC_REASON_FLAG_REMOTE|END_CIRC_REASON_OR_CONN_CLOSED);
return 0;
#if 0
while (layer->next != circ->cpath) {
/* we need to clear out layer->next */
victim = layer->next;
log_debug(LD_CIRC, "Killing a layer of the cpath.");
for (stream = circ->p_streams; stream; stream=stream->next_stream) {
if (stream->cpath_layer == victim) {
log_info(LD_APP, "Marking stream %d for close because of truncate.",
stream->stream_id);
/* no need to send 'end' relay cells,
* because the other side's already dead
*/
connection_mark_unattached_ap(stream, END_STREAM_REASON_DESTROY);
}
}
layer->next = victim->next;
circuit_free_cpath_node(victim);
}
log_info(LD_CIRC, "finished");
return 0;
#endif
}
/** Given a response payload and keys, initialize, then send a created
* cell back.
*/
int
onionskin_answer(or_circuit_t *circ, uint8_t cell_type, const char *payload,
const char *keys)
{
cell_t cell;
crypt_path_t *tmp_cpath;
tmp_cpath = tor_malloc_zero(sizeof(crypt_path_t));
tmp_cpath->magic = CRYPT_PATH_MAGIC;
memset(&cell, 0, sizeof(cell_t));
cell.command = cell_type;
cell.circ_id = circ->p_circ_id;
circuit_set_state(TO_CIRCUIT(circ), CIRCUIT_STATE_OPEN);
memcpy(cell.payload, payload,
cell_type == CELL_CREATED ? ONIONSKIN_REPLY_LEN : DIGEST_LEN*2);
log_debug(LD_CIRC,"init digest forward 0x%.8x, backward 0x%.8x.",
(unsigned int)get_uint32(keys),
(unsigned int)get_uint32(keys+20));
if (circuit_init_cpath_crypto(tmp_cpath, keys, 0)<0) {
log_warn(LD_BUG,"Circuit initialization failed");
tor_free(tmp_cpath);
return -1;
}
circ->n_digest = tmp_cpath->f_digest;
circ->n_crypto = tmp_cpath->f_crypto;
circ->p_digest = tmp_cpath->b_digest;
circ->p_crypto = tmp_cpath->b_crypto;
tmp_cpath->magic = 0;
tor_free(tmp_cpath);
if (cell_type == CELL_CREATED)
memcpy(circ->handshake_digest, cell.payload+DH_KEY_LEN, DIGEST_LEN);
else
memcpy(circ->handshake_digest, cell.payload+DIGEST_LEN, DIGEST_LEN);
circ->is_first_hop = (cell_type == CELL_CREATED_FAST);
append_cell_to_circuit_queue(TO_CIRCUIT(circ),
circ->p_conn, &cell, CELL_DIRECTION_IN, 0);
log_debug(LD_CIRC,"Finished sending 'created' cell.");
if (!is_local_addr(&circ->p_conn->_base.addr) &&
!connection_or_nonopen_was_started_here(circ->p_conn)) {
/* record that we could process create cells from a non-local conn
* that we didn't initiate; presumably this means that create cells
* can reach us too. */
router_orport_found_reachable();
}
return 0;
}
/** Choose a length for a circuit of purpose <b>purpose</b>.
* Default length is 3 + the number of endpoints that would give something
* away. If the routerlist <b>routers</b> doesn't have enough routers
* to handle the desired path length, return as large a path length as
* is feasible, except if it's less than 2, in which case return -1.
*/
static int
new_route_len(uint8_t purpose, extend_info_t *exit,
smartlist_t *nodes)
{
int num_acceptable_routers;
int routelen;
tor_assert(nodes);
routelen = DEFAULT_ROUTE_LEN;
if (exit &&
purpose != CIRCUIT_PURPOSE_TESTING &&
purpose != CIRCUIT_PURPOSE_S_ESTABLISH_INTRO)
routelen++;
num_acceptable_routers = count_acceptable_nodes(nodes);
log_debug(LD_CIRC,"Chosen route length %d (%d/%d routers suitable).",
routelen, num_acceptable_routers, smartlist_len(nodes));
if (num_acceptable_routers < 2) {
log_info(LD_CIRC,
"Not enough acceptable routers (%d). Discarding this circuit.",
num_acceptable_routers);
return -1;
}
if (num_acceptable_routers < routelen) {
log_info(LD_CIRC,"Not enough routers: cutting routelen from %d to %d.",
routelen, num_acceptable_routers);
routelen = num_acceptable_routers;
}
return routelen;
}
/** Return a newly allocated list of uint16_t * for each predicted port not
* handled by a current circuit. */
static smartlist_t *
circuit_get_unhandled_ports(time_t now)
{
smartlist_t *dest = rep_hist_get_predicted_ports(now);
circuit_remove_handled_ports(dest);
return dest;
}
/** Return 1 if we already have circuits present or on the way for
* all anticipated ports. Return 0 if we should make more.
*
* If we're returning 0, set need_uptime and need_capacity to
* indicate any requirements that the unhandled ports have.
*/
int
circuit_all_predicted_ports_handled(time_t now, int *need_uptime,
int *need_capacity)
{
int i, enough;
uint16_t *port;
smartlist_t *sl = circuit_get_unhandled_ports(now);
smartlist_t *LongLivedServices = get_options()->LongLivedPorts;
tor_assert(need_uptime);
tor_assert(need_capacity);
// Always predict need_capacity
*need_capacity = 1;
enough = (smartlist_len(sl) == 0);
for (i = 0; i < smartlist_len(sl); ++i) {
port = smartlist_get(sl, i);
if (smartlist_string_num_isin(LongLivedServices, *port))
*need_uptime = 1;
tor_free(port);
}
smartlist_free(sl);
return enough;
}
/** Return 1 if <b>node</b> can handle one or more of the ports in
* <b>needed_ports</b>, else return 0.
*/
static int
node_handles_some_port(const node_t *node, smartlist_t *needed_ports)
{ /* XXXX MOVE */
int i;
uint16_t port;
for (i = 0; i < smartlist_len(needed_ports); ++i) {
addr_policy_result_t r;
/* alignment issues aren't a worry for this dereference, since
needed_ports is explicitly a smartlist of uint16_t's */
port = *(uint16_t *)smartlist_get(needed_ports, i);
tor_assert(port);
if (node)
r = compare_tor_addr_to_node_policy(NULL, port, node);
else
continue;
if (r != ADDR_POLICY_REJECTED && r != ADDR_POLICY_PROBABLY_REJECTED)
return 1;
}
return 0;
}
/** Return true iff <b>conn</b> needs another general circuit to be
* built. */
static int
ap_stream_wants_exit_attention(connection_t *conn)
{
if (conn->type == CONN_TYPE_AP &&
conn->state == AP_CONN_STATE_CIRCUIT_WAIT &&
!conn->marked_for_close &&
!(TO_EDGE_CONN(conn)->want_onehop) && /* ignore one-hop streams */
!(TO_EDGE_CONN(conn)->use_begindir) && /* ignore targeted dir fetches */
!(TO_EDGE_CONN(conn)->chosen_exit_name) && /* ignore defined streams */
!connection_edge_is_rendezvous_stream(TO_EDGE_CONN(conn)) &&
!circuit_stream_is_being_handled(TO_EDGE_CONN(conn), 0,
MIN_CIRCUITS_HANDLING_STREAM))
return 1;
return 0;
}
/** Return a pointer to a suitable router to be the exit node for the
* general-purpose circuit we're about to build.
*
* Look through the connection array, and choose a router that maximizes
* the number of pending streams that can exit from this router.
*
* Return NULL if we can't find any suitable routers.
*/
static const node_t *
choose_good_exit_server_general(int need_uptime, int need_capacity)
{
int *n_supported;
int n_pending_connections = 0;
smartlist_t *connections;
int best_support = -1;
int n_best_support=0;
const or_options_t *options = get_options();
const smartlist_t *the_nodes;
const node_t *node=NULL;
connections = get_connection_array();
/* Count how many connections are waiting for a circuit to be built.
* We use this for log messages now, but in the future we may depend on it.
*/
SMARTLIST_FOREACH(connections, connection_t *, conn,
{
if (ap_stream_wants_exit_attention(conn))
++n_pending_connections;
});
// log_fn(LOG_DEBUG, "Choosing exit node; %d connections are pending",
// n_pending_connections);
/* Now we count, for each of the routers in the directory, how many
* of the pending connections could possibly exit from that
* router (n_supported[i]). (We can't be sure about cases where we
* don't know the IP address of the pending connection.)
*
* -1 means "Don't use this router at all."
*/
the_nodes = nodelist_get_list();
n_supported = tor_malloc(sizeof(int)*smartlist_len(the_nodes));
SMARTLIST_FOREACH_BEGIN(the_nodes, const node_t *, node) {
const int i = node_sl_idx;
if (router_digest_is_me(node->identity)) {
n_supported[i] = -1;
// log_fn(LOG_DEBUG,"Skipping node %s -- it's me.", router->nickname);
/* XXX there's probably a reverse predecessor attack here, but
* it's slow. should we take this out? -RD
*/
continue;
}
if (!node_has_descriptor(node)) {
n_supported[i] = -1;
continue;
}
if (!node->is_running || node->is_bad_exit) {
n_supported[i] = -1;
continue; /* skip routers that are known to be down or bad exits */
}
if (routerset_contains_node(options->_ExcludeExitNodesUnion, node)) {
n_supported[i] = -1;
continue; /* user asked us not to use it, no matter what */
}
if (options->ExitNodes &&
!routerset_contains_node(options->ExitNodes, node)) {
n_supported[i] = -1;
continue; /* not one of our chosen exit nodes */
}
if (node_is_unreliable(node, need_uptime, need_capacity, 0)) {
n_supported[i] = -1;
continue; /* skip routers that are not suitable. Don't worry if
* this makes us reject all the possible routers: if so,
* we'll retry later in this function with need_update and
* need_capacity set to 0. */
}
if (!(node->is_valid || options->_AllowInvalid & ALLOW_INVALID_EXIT)) {
/* if it's invalid and we don't want it */
n_supported[i] = -1;
// log_fn(LOG_DEBUG,"Skipping node %s (index %d) -- invalid router.",
// router->nickname, i);
continue; /* skip invalid routers */
}
if (options->ExcludeSingleHopRelays &&
node_allows_single_hop_exits(node)) {
n_supported[i] = -1;
continue;
}
if (node_exit_policy_rejects_all(node)) {
n_supported[i] = -1;
// log_fn(LOG_DEBUG,"Skipping node %s (index %d) -- it rejects all.",
// router->nickname, i);
continue; /* skip routers that reject all */
}
n_supported[i] = 0;
/* iterate over connections */
SMARTLIST_FOREACH_BEGIN(connections, connection_t *, conn) {
if (!ap_stream_wants_exit_attention(conn))
continue; /* Skip everything but APs in CIRCUIT_WAIT */
if (connection_ap_can_use_exit(TO_EDGE_CONN(conn), node)) {
++n_supported[i];
// log_fn(LOG_DEBUG,"%s is supported. n_supported[%d] now %d.",
// router->nickname, i, n_supported[i]);
} else {
// log_fn(LOG_DEBUG,"%s (index %d) would reject this stream.",
// router->nickname, i);
}
} SMARTLIST_FOREACH_END(conn);
if (n_pending_connections > 0 && n_supported[i] == 0) {
/* Leave best_support at -1 if that's where it is, so we can
* distinguish it later. */
continue;
}
if (n_supported[i] > best_support) {
/* If this router is better than previous ones, remember its index
* and goodness, and start counting how many routers are this good. */
best_support = n_supported[i]; n_best_support=1;
// log_fn(LOG_DEBUG,"%s is new best supported option so far.",
// router->nickname);
} else if (n_supported[i] == best_support) {
/* If this router is _as good_ as the best one, just increment the
* count of equally good routers.*/
++n_best_support;
}
} SMARTLIST_FOREACH_END(node);
log_info(LD_CIRC,
"Found %d servers that might support %d/%d pending connections.",
n_best_support, best_support >= 0 ? best_support : 0,
n_pending_connections);
/* If any routers definitely support any pending connections, choose one
* at random. */
if (best_support > 0) {
smartlist_t *supporting = smartlist_create();
SMARTLIST_FOREACH(the_nodes, const node_t *, node, {
if (n_supported[node_sl_idx] == best_support)
smartlist_add(supporting, (void*)node);
});
node = node_sl_choose_by_bandwidth(supporting, WEIGHT_FOR_EXIT);
smartlist_free(supporting);
} else {
/* Either there are no pending connections, or no routers even seem to
* possibly support any of them. Choose a router at random that satisfies
* at least one predicted exit port. */
int attempt;
smartlist_t *needed_ports, *supporting;
if (best_support == -1) {
if (need_uptime || need_capacity) {
log_info(LD_CIRC,
"We couldn't find any live%s%s routers; falling back "
"to list of all routers.",
need_capacity?", fast":"",
need_uptime?", stable":"");
tor_free(n_supported);
return choose_good_exit_server_general(0, 0);
}
log_notice(LD_CIRC, "All routers are down or won't exit%s -- "
"choosing a doomed exit at random.",
options->_ExcludeExitNodesUnion ? " or are Excluded" : "");
}
supporting = smartlist_create();
needed_ports = circuit_get_unhandled_ports(time(NULL));
for (attempt = 0; attempt < 2; attempt++) {
/* try once to pick only from routers that satisfy a needed port,
* then if there are none, pick from any that support exiting. */
SMARTLIST_FOREACH_BEGIN(the_nodes, const node_t *, node) {
if (n_supported[node_sl_idx] != -1 &&
(attempt || node_handles_some_port(node, needed_ports))) {
// log_fn(LOG_DEBUG,"Try %d: '%s' is a possibility.",
// try, router->nickname);
smartlist_add(supporting, (void*)node);
}
} SMARTLIST_FOREACH_END(node);
node = node_sl_choose_by_bandwidth(supporting, WEIGHT_FOR_EXIT);
if (node)
break;
smartlist_clear(supporting);
}
SMARTLIST_FOREACH(needed_ports, uint16_t *, cp, tor_free(cp));
smartlist_free(needed_ports);
smartlist_free(supporting);
}
tor_free(n_supported);
if (node) {
log_info(LD_CIRC, "Chose exit server '%s'", node_describe(node));
return node;
}
if (options->ExitNodes) {
log_warn(LD_CIRC,
"No specified %sexit routers seem to be running: "
"can't choose an exit.",
options->_ExcludeExitNodesUnion ? "non-excluded " : "");
}
return NULL;
}
/** Return a pointer to a suitable router to be the exit node for the
* circuit of purpose <b>purpose</b> that we're about to build (or NULL
* if no router is suitable).
*
* For general-purpose circuits, pass it off to
* choose_good_exit_server_general()
*
* For client-side rendezvous circuits, choose a random node, weighted
* toward the preferences in 'options'.
*/
static const node_t *
choose_good_exit_server(uint8_t purpose,
int need_uptime, int need_capacity, int is_internal)
{
const or_options_t *options = get_options();
router_crn_flags_t flags = CRN_NEED_DESC;
if (need_uptime)
flags |= CRN_NEED_UPTIME;
if (need_capacity)
flags |= CRN_NEED_CAPACITY;
switch (purpose) {
case CIRCUIT_PURPOSE_C_GENERAL:
if (options->_AllowInvalid & ALLOW_INVALID_MIDDLE)
flags |= CRN_ALLOW_INVALID;
if (is_internal) /* pick it like a middle hop */
return router_choose_random_node(NULL, options->ExcludeNodes, flags);
else
return choose_good_exit_server_general(need_uptime,need_capacity);
case CIRCUIT_PURPOSE_C_ESTABLISH_REND:
if (options->_AllowInvalid & ALLOW_INVALID_RENDEZVOUS)
flags |= CRN_ALLOW_INVALID;
return router_choose_random_node(NULL, options->ExcludeNodes, flags);
}
log_warn(LD_BUG,"Unhandled purpose %d", purpose);
tor_fragile_assert();
return NULL;
}
/** Log a warning if the user specified an exit for the circuit that
* has been excluded from use by ExcludeNodes or ExcludeExitNodes. */
static void
warn_if_last_router_excluded(origin_circuit_t *circ, const extend_info_t *exit)
{
const or_options_t *options = get_options();
routerset_t *rs = options->ExcludeNodes;
const char *description;
uint8_t purpose = circ->_base.purpose;
if (circ->build_state->onehop_tunnel)
return;
switch (purpose)
{
default:
case CIRCUIT_PURPOSE_OR:
case CIRCUIT_PURPOSE_INTRO_POINT:
case CIRCUIT_PURPOSE_REND_POINT_WAITING:
case CIRCUIT_PURPOSE_REND_ESTABLISHED:
log_warn(LD_BUG, "Called on non-origin circuit (purpose %d, %s)",
(int)purpose,
circuit_purpose_to_string(purpose));
return;
case CIRCUIT_PURPOSE_C_GENERAL:
if (circ->build_state->is_internal)
return;
description = "requested exit node";
rs = options->_ExcludeExitNodesUnion;
break;
case CIRCUIT_PURPOSE_C_INTRODUCING:
case CIRCUIT_PURPOSE_C_INTRODUCE_ACK_WAIT:
case CIRCUIT_PURPOSE_C_INTRODUCE_ACKED:
case CIRCUIT_PURPOSE_S_ESTABLISH_INTRO:
case CIRCUIT_PURPOSE_S_CONNECT_REND:
case CIRCUIT_PURPOSE_S_REND_JOINED:
case CIRCUIT_PURPOSE_TESTING:
return;
case CIRCUIT_PURPOSE_C_ESTABLISH_REND:
case CIRCUIT_PURPOSE_C_REND_READY:
case CIRCUIT_PURPOSE_C_REND_READY_INTRO_ACKED:
case CIRCUIT_PURPOSE_C_REND_JOINED:
description = "chosen rendezvous point";
break;
case CIRCUIT_PURPOSE_CONTROLLER:
rs = options->_ExcludeExitNodesUnion;
description = "controller-selected circuit target";
break;
}
if (routerset_contains_extendinfo(rs, exit)) {
/* We should never get here if StrictNodes is set to 1. */
if (options->StrictNodes) {
log_warn(LD_BUG, "Using %s '%s' which is listed in ExcludeNodes%s, "
"even though StrictNodes is set. Please report. "
"(Circuit purpose: %s)",
description, extend_info_describe(exit),
rs==options->ExcludeNodes?"":" or ExcludeExitNodes",
circuit_purpose_to_string(purpose));
} else {
log_warn(LD_CIRC, "Using %s '%s' which is listed in "
"ExcludeNodes%s, because no better options were available. To "
"prevent this (and possibly break your Tor functionality), "
"set the StrictNodes configuration option. "
"(Circuit purpose: %s)",
description, extend_info_describe(exit),
rs==options->ExcludeNodes?"":" or ExcludeExitNodes",
circuit_purpose_to_string(purpose));
}
circuit_log_path(LOG_WARN, LD_CIRC, circ);
}
return;
}
/** Decide a suitable length for circ's cpath, and pick an exit
* router (or use <b>exit</b> if provided). Store these in the
* cpath. Return 0 if ok, -1 if circuit should be closed. */
static int
onion_pick_cpath_exit(origin_circuit_t *circ, extend_info_t *exit)
{
cpath_build_state_t *state = circ->build_state;
if (state->onehop_tunnel) {
log_debug(LD_CIRC, "Launching a one-hop circuit for dir tunnel.");
state->desired_path_len = 1;
} else {
int r = new_route_len(circ->_base.purpose, exit, nodelist_get_list());
if (r < 1) /* must be at least 1 */
return -1;
state->desired_path_len = r;
}
if (exit) { /* the circuit-builder pre-requested one */
warn_if_last_router_excluded(circ, exit);
log_info(LD_CIRC,"Using requested exit node '%s'",
extend_info_describe(exit));
exit = extend_info_dup(exit);
} else { /* we have to decide one */
const node_t *node =
choose_good_exit_server(circ->_base.purpose, state->need_uptime,
state->need_capacity, state->is_internal);
if (!node) {
log_warn(LD_CIRC,"failed to choose an exit server");
return -1;
}
exit = extend_info_from_node(node);
tor_assert(exit);
}
state->chosen_exit = exit;
return 0;
}
/** Give <b>circ</b> a new exit destination to <b>exit</b>, and add a
* hop to the cpath reflecting this. Don't send the next extend cell --
* the caller will do this if it wants to.
*/
int
circuit_append_new_exit(origin_circuit_t *circ, extend_info_t *exit)
{
cpath_build_state_t *state;
tor_assert(exit);
tor_assert(circ);
state = circ->build_state;
tor_assert(state);
extend_info_free(state->chosen_exit);
state->chosen_exit = extend_info_dup(exit);
++circ->build_state->desired_path_len;
onion_append_hop(&circ->cpath, exit);
return 0;
}
/** Take an open <b>circ</b>, and add a new hop at the end, based on
* <b>info</b>. Set its state back to CIRCUIT_STATE_BUILDING, and then
* send the next extend cell to begin connecting to that hop.
*/
int
circuit_extend_to_new_exit(origin_circuit_t *circ, extend_info_t *exit)
{
int err_reason = 0;
warn_if_last_router_excluded(circ, exit);
circuit_append_new_exit(circ, exit);
circuit_set_state(TO_CIRCUIT(circ), CIRCUIT_STATE_BUILDING);
if ((err_reason = circuit_send_next_onion_skin(circ))<0) {
log_warn(LD_CIRC, "Couldn't extend circuit to new point %s.",
extend_info_describe(exit));
circuit_mark_for_close(TO_CIRCUIT(circ), -err_reason);
return -1;
}
return 0;
}
/** Return the number of routers in <b>routers</b> that are currently up
* and available for building circuits through.
*/
static int
count_acceptable_nodes(smartlist_t *nodes)
{
int num=0;
SMARTLIST_FOREACH_BEGIN(nodes, const node_t *, node) {
// log_debug(LD_CIRC,
// "Contemplating whether router %d (%s) is a new option.",
// i, r->nickname);
if (! node->is_running)
// log_debug(LD_CIRC,"Nope, the directory says %d is not running.",i);
continue;
if (! node->is_valid)
// log_debug(LD_CIRC,"Nope, the directory says %d is not valid.",i);
continue;
if (! node_has_descriptor(node))
continue;
/* XXX This clause makes us count incorrectly: if AllowInvalidRouters
* allows this node in some places, then we're getting an inaccurate
* count. For now, be conservative and don't count it. But later we
* should try to be smarter. */
++num;
} SMARTLIST_FOREACH_END(node);
// log_debug(LD_CIRC,"I like %d. num_acceptable_routers now %d.",i, num);
return num;
}
/** Add <b>new_hop</b> to the end of the doubly-linked-list <b>head_ptr</b>.
* This function is used to extend cpath by another hop.
*/
void
onion_append_to_cpath(crypt_path_t **head_ptr, crypt_path_t *new_hop)
{
if (*head_ptr) {
new_hop->next = (*head_ptr);
new_hop->prev = (*head_ptr)->prev;
(*head_ptr)->prev->next = new_hop;
(*head_ptr)->prev = new_hop;
} else {
*head_ptr = new_hop;
new_hop->prev = new_hop->next = new_hop;
}
}
/** A helper function used by onion_extend_cpath(). Use <b>purpose</b>
* and <b>state</b> and the cpath <b>head</b> (currently populated only
* to length <b>cur_len</b> to decide a suitable middle hop for a
* circuit. In particular, make sure we don't pick the exit node or its
* family, and make sure we don't duplicate any previous nodes or their
* families. */
static const node_t *
choose_good_middle_server(uint8_t purpose,
cpath_build_state_t *state,
crypt_path_t *head,
int cur_len)
{
int i;
const node_t *r, *choice;
crypt_path_t *cpath;
smartlist_t *excluded;
const or_options_t *options = get_options();
router_crn_flags_t flags = CRN_NEED_DESC;
tor_assert(_CIRCUIT_PURPOSE_MIN <= purpose &&
purpose <= _CIRCUIT_PURPOSE_MAX);
log_debug(LD_CIRC, "Contemplating intermediate hop: random choice.");
excluded = smartlist_create();
if ((r = build_state_get_exit_node(state))) {
nodelist_add_node_and_family(excluded, r);
}
for (i = 0, cpath = head; i < cur_len; ++i, cpath=cpath->next) {
if ((r = node_get_by_id(cpath->extend_info->identity_digest))) {
nodelist_add_node_and_family(excluded, r);
}
}
if (state->need_uptime)
flags |= CRN_NEED_UPTIME;
if (state->need_capacity)
flags |= CRN_NEED_CAPACITY;
if (options->_AllowInvalid & ALLOW_INVALID_MIDDLE)
flags |= CRN_ALLOW_INVALID;
choice = router_choose_random_node(excluded, options->ExcludeNodes, flags);
smartlist_free(excluded);
return choice;
}
/** Pick a good entry server for the circuit to be built according to
* <b>state</b>. Don't reuse a chosen exit (if any), don't use this
* router (if we're an OR), and respect firewall settings; if we're
* configured to use entry guards, return one.
*
* If <b>state</b> is NULL, we're choosing a router to serve as an entry
* guard, not for any particular circuit.
*/
static const node_t *
choose_good_entry_server(uint8_t purpose, cpath_build_state_t *state)
{
const node_t *choice;
smartlist_t *excluded;
const or_options_t *options = get_options();
router_crn_flags_t flags = CRN_NEED_GUARD|CRN_NEED_DESC;
const node_t *node;
if (state && options->UseEntryGuards &&
(purpose != CIRCUIT_PURPOSE_TESTING || options->BridgeRelay)) {
/* This is request for an entry server to use for a regular circuit,
* and we use entry guard nodes. Just return one of the guard nodes. */
return choose_random_entry(state);
}
excluded = smartlist_create();
if (state && (node = build_state_get_exit_node(state))) {
/* Exclude the exit node from the state, if we have one. Also exclude its
* family. */
nodelist_add_node_and_family(excluded, node);
}
if (firewall_is_fascist_or()) {
/* Exclude all ORs that we can't reach through our firewall */
smartlist_t *nodes = nodelist_get_list();
SMARTLIST_FOREACH(nodes, const node_t *, node, {
if (!fascist_firewall_allows_node(node))
smartlist_add(excluded, (void*)node);
});
}
/* and exclude current entry guards and their families, if applicable */
if (options->UseEntryGuards && entry_guards) {
SMARTLIST_FOREACH(entry_guards, entry_guard_t *, entry,
{
if ((node = node_get_by_id(entry->identity))) {
nodelist_add_node_and_family(excluded, node);
}
});
}
if (state) {
if (state->need_uptime)
flags |= CRN_NEED_UPTIME;
if (state->need_capacity)
flags |= CRN_NEED_CAPACITY;
}
if (options->_AllowInvalid & ALLOW_INVALID_ENTRY)
flags |= CRN_ALLOW_INVALID;
choice = router_choose_random_node(excluded, options->ExcludeNodes, flags);
smartlist_free(excluded);
return choice;
}
/** Return the first non-open hop in cpath, or return NULL if all
* hops are open. */
static crypt_path_t *
onion_next_hop_in_cpath(crypt_path_t *cpath)
{
crypt_path_t *hop = cpath;
do {
if (hop->state != CPATH_STATE_OPEN)
return hop;
hop = hop->next;
} while (hop != cpath);
return NULL;
}
/** Choose a suitable next hop in the cpath <b>head_ptr</b>,
* based on <b>state</b>. Append the hop info to head_ptr.
*/
static int
onion_extend_cpath(origin_circuit_t *circ)
{
uint8_t purpose = circ->_base.purpose;
cpath_build_state_t *state = circ->build_state;
int cur_len = circuit_get_cpath_len(circ);
extend_info_t *info = NULL;
if (cur_len >= state->desired_path_len) {
log_debug(LD_CIRC, "Path is complete: %d steps long",
state->desired_path_len);
return 1;
}
log_debug(LD_CIRC, "Path is %d long; we want %d", cur_len,
state->desired_path_len);
if (cur_len == state->desired_path_len - 1) { /* Picking last node */
info = extend_info_dup(state->chosen_exit);
} else if (cur_len == 0) { /* picking first node */
const node_t *r = choose_good_entry_server(purpose, state);
if (r) {
info = extend_info_from_node(r);
tor_assert(info);
}
} else {
const node_t *r =
choose_good_middle_server(purpose, state, circ->cpath, cur_len);
if (r) {
info = extend_info_from_node(r);
tor_assert(info);
}
}
if (!info) {
log_warn(LD_CIRC,"Failed to find node for hop %d of our path. Discarding "
"this circuit.", cur_len);
return -1;
}
log_debug(LD_CIRC,"Chose router %s for hop %d (exit is %s)",
extend_info_describe(info),
cur_len+1, build_state_get_exit_nickname(state));
onion_append_hop(&circ->cpath, info);
extend_info_free(info);
return 0;
}
/** Create a new hop, annotate it with information about its
* corresponding router <b>choice</b>, and append it to the
* end of the cpath <b>head_ptr</b>. */
static int
onion_append_hop(crypt_path_t **head_ptr, extend_info_t *choice)
{
crypt_path_t *hop = tor_malloc_zero(sizeof(crypt_path_t));
/* link hop into the cpath, at the end. */
onion_append_to_cpath(head_ptr, hop);
hop->magic = CRYPT_PATH_MAGIC;
hop->state = CPATH_STATE_CLOSED;
hop->extend_info = extend_info_dup(choice);
hop->package_window = circuit_initial_package_window();
hop->deliver_window = CIRCWINDOW_START;
return 0;
}
/** Allocate a new extend_info object based on the various arguments. */
extend_info_t *
extend_info_alloc(const char *nickname, const char *digest,
crypto_pk_env_t *onion_key,
const tor_addr_t *addr, uint16_t port)
{
extend_info_t *info = tor_malloc_zero(sizeof(extend_info_t));
memcpy(info->identity_digest, digest, DIGEST_LEN);
if (nickname)
strlcpy(info->nickname, nickname, sizeof(info->nickname));
if (onion_key)
info->onion_key = crypto_pk_dup_key(onion_key);
tor_addr_copy(&info->addr, addr);
info->port = port;
return info;
}
/** Allocate and return a new extend_info_t that can be used to build a
* circuit to or through the router <b>r</b>. */
extend_info_t *
extend_info_from_router(const routerinfo_t *r)
{
tor_addr_t addr;
tor_assert(r);
tor_addr_from_ipv4h(&addr, r->addr);
return extend_info_alloc(r->nickname, r->cache_info.identity_digest,
r->onion_pkey, &addr, r->or_port);
}
/** Allocate and return a new extend_info that can be used to build a ircuit
* to or through the node <b>node</b>. May return NULL if there is not
* enough info about <b>node</b> to extend to it--for example, if there
* is no routerinfo_t or microdesc_t.
**/
extend_info_t *
extend_info_from_node(const node_t *node)
{
if (node->ri) {
return extend_info_from_router(node->ri);
} else if (node->rs && node->md) {
tor_addr_t addr;
tor_addr_from_ipv4h(&addr, node->rs->addr);
return extend_info_alloc(node->rs->nickname,
node->identity,
node->md->onion_pkey,
&addr,
node->rs->or_port);
} else {
return NULL;
}
}
/** Release storage held by an extend_info_t struct. */
void
extend_info_free(extend_info_t *info)
{
if (!info)
return;
crypto_free_pk_env(info->onion_key);
tor_free(info);
}
/** Allocate and return a new extend_info_t with the same contents as
* <b>info</b>. */
extend_info_t *
extend_info_dup(extend_info_t *info)
{
extend_info_t *newinfo;
tor_assert(info);
newinfo = tor_malloc(sizeof(extend_info_t));
memcpy(newinfo, info, sizeof(extend_info_t));
if (info->onion_key)
newinfo->onion_key = crypto_pk_dup_key(info->onion_key);
else
newinfo->onion_key = NULL;
return newinfo;
}
/** Return the routerinfo_t for the chosen exit router in <b>state</b>.
* If there is no chosen exit, or if we don't know the routerinfo_t for
* the chosen exit, return NULL.
*/
const node_t *
build_state_get_exit_node(cpath_build_state_t *state)
{
if (!state || !state->chosen_exit)
return NULL;
return node_get_by_id(state->chosen_exit->identity_digest);
}
/** Return the nickname for the chosen exit router in <b>state</b>. If
* there is no chosen exit, or if we don't know the routerinfo_t for the
* chosen exit, return NULL.
*/
const char *
build_state_get_exit_nickname(cpath_build_state_t *state)
{
if (!state || !state->chosen_exit)
return NULL;
return state->chosen_exit->nickname;
}
/** Check whether the entry guard <b>e</b> is usable, given the directory
* authorities' opinion about the router (stored in <b>ri</b>) and the user's
* configuration (in <b>options</b>). Set <b>e</b>-&gt;bad_since
* accordingly. Return true iff the entry guard's status changes.
*
* If it's not usable, set *<b>reason</b> to a static string explaining why.
*/
static int
entry_guard_set_status(entry_guard_t *e, const node_t *node,
time_t now, const or_options_t *options,
const char **reason)
{
char buf[HEX_DIGEST_LEN+1];
int changed = 0;
*reason = NULL;
/* Do we want to mark this guard as bad? */
if (!node)
*reason = "unlisted";
else if (!node->is_running)
*reason = "down";
else if (options->UseBridges && (!node->ri ||
node->ri->purpose != ROUTER_PURPOSE_BRIDGE))
*reason = "not a bridge";
else if (options->UseBridges && !node_is_a_configured_bridge(node))
*reason = "not a configured bridge";
else if (!options->UseBridges && !node->is_possible_guard &&
!routerset_contains_node(options->EntryNodes,node))
*reason = "not recommended as a guard";
else if (routerset_contains_node(options->ExcludeNodes, node))
*reason = "excluded";
if (*reason && ! e->bad_since) {
/* Router is newly bad. */
base16_encode(buf, sizeof(buf), e->identity, DIGEST_LEN);
log_info(LD_CIRC, "Entry guard %s (%s) is %s: marking as unusable.",
e->nickname, buf, *reason);
e->bad_since = now;
control_event_guard(e->nickname, e->identity, "BAD");
changed = 1;
} else if (!*reason && e->bad_since) {
/* There's nothing wrong with the router any more. */
base16_encode(buf, sizeof(buf), e->identity, DIGEST_LEN);
log_info(LD_CIRC, "Entry guard %s (%s) is no longer unusable: "
"marking as ok.", e->nickname, buf);
e->bad_since = 0;
control_event_guard(e->nickname, e->identity, "GOOD");
changed = 1;
}
return changed;
}
/** Return true iff enough time has passed since we last tried to connect
* to the unreachable guard <b>e</b> that we're willing to try again. */
static int
entry_is_time_to_retry(entry_guard_t *e, time_t now)
{
long diff;
if (e->last_attempted < e->unreachable_since)
return 1;
diff = now - e->unreachable_since;
if (diff < 6*60*60)
return now > (e->last_attempted + 60*60);
else if (diff < 3*24*60*60)
return now > (e->last_attempted + 4*60*60);
else if (diff < 7*24*60*60)
return now > (e->last_attempted + 18*60*60);
else
return now > (e->last_attempted + 36*60*60);
}
/** Return the node corresponding to <b>e</b>, if <b>e</b> is
* working well enough that we are willing to use it as an entry
* right now. (Else return NULL.) In particular, it must be
* - Listed as either up or never yet contacted;
* - Present in the routerlist;
* - Listed as 'stable' or 'fast' by the current dirserver consensus,
* if demanded by <b>need_uptime</b> or <b>need_capacity</b>
* (unless it's a configured EntryNode);
* - Allowed by our current ReachableORAddresses config option; and
* - Currently thought to be reachable by us (unless <b>assume_reachable</b>
* is true).
*
* If the answer is no, set *<b>msg</b> to an explanation of why.
*/
static INLINE const node_t *
entry_is_live(entry_guard_t *e, int need_uptime, int need_capacity,
int assume_reachable, const char **msg)
{
const node_t *node;
const or_options_t *options = get_options();
tor_assert(msg);
if (e->bad_since) {
*msg = "bad";
return NULL;
}
/* no good if it's unreachable, unless assume_unreachable or can_retry. */
if (!assume_reachable && !e->can_retry &&
e->unreachable_since && !entry_is_time_to_retry(e, time(NULL))) {
*msg = "unreachable";
return NULL;
}
node = node_get_by_id(e->identity);
if (!node || !node_has_descriptor(node)) {
*msg = "no descriptor";
return NULL;
}
if (get_options()->UseBridges) {
if (node_get_purpose(node) != ROUTER_PURPOSE_BRIDGE) {
*msg = "not a bridge";
return NULL;
}
if (!node_is_a_configured_bridge(node)) {
*msg = "not a configured bridge";
return NULL;
}
} else { /* !get_options()->UseBridges */
if (node_get_purpose(node) != ROUTER_PURPOSE_GENERAL) {
*msg = "not general-purpose";
return NULL;
}
}
if (routerset_contains_node(options->EntryNodes, node)) {
/* they asked for it, they get it */
need_uptime = need_capacity = 0;
}
if (node_is_unreliable(node, need_uptime, need_capacity, 0)) {
*msg = "not fast/stable";
return NULL;
}
if (!fascist_firewall_allows_node(node)) {
*msg = "unreachable by config";
return NULL;
}
return node;
}
/** Return the number of entry guards that we think are usable. */
static int
num_live_entry_guards(void)
{
int n = 0;
const char *msg;
if (! entry_guards)
return 0;
SMARTLIST_FOREACH(entry_guards, entry_guard_t *, entry,
{
if (entry_is_live(entry, 0, 1, 0, &msg))
++n;
});
return n;
}
/** If <b>digest</b> matches the identity of any node in the
* entry_guards list, return that node. Else return NULL. */
static INLINE entry_guard_t *
is_an_entry_guard(const char *digest)
{
SMARTLIST_FOREACH(entry_guards, entry_guard_t *, entry,
if (tor_memeq(digest, entry->identity, DIGEST_LEN))
return entry;
);
return NULL;
}
/** Dump a description of our list of entry guards to the log at level
* <b>severity</b>. */
static void
log_entry_guards(int severity)
{
smartlist_t *elements = smartlist_create();
char *s;
SMARTLIST_FOREACH_BEGIN(entry_guards, entry_guard_t *, e)
{
const char *msg = NULL;
char *cp;
if (entry_is_live(e, 0, 1, 0, &msg))
tor_asprintf(&cp, "%s [%s] (up %s)",
e->nickname,
hex_str(e->identity, DIGEST_LEN),
e->made_contact ? "made-contact" : "never-contacted");
else
tor_asprintf(&cp, "%s [%s] (%s, %s)",
e->nickname,
hex_str(e->identity, DIGEST_LEN),
msg,
e->made_contact ? "made-contact" : "never-contacted");
smartlist_add(elements, cp);
}
SMARTLIST_FOREACH_END(e);
s = smartlist_join_strings(elements, ",", 0, NULL);
SMARTLIST_FOREACH(elements, char*, cp, tor_free(cp));
smartlist_free(elements);
log_fn(severity,LD_CIRC,"%s",s);
tor_free(s);
}
/** Called when one or more guards that we would previously have used for some
* purpose are no longer in use because a higher-priority guard has become
* usable again. */
static void
control_event_guard_deferred(void)
{
/* XXXX We don't actually have a good way to figure out _how many_ entries
* are live for some purpose. We need an entry_is_even_slightly_live()
* function for this to work right. NumEntryGuards isn't reliable: if we
* need guards with weird properties, we can have more than that number
* live.
**/
#if 0
int n = 0;
const char *msg;
const or_options_t *options = get_options();
if (!entry_guards)
return;
SMARTLIST_FOREACH(entry_guards, entry_guard_t *, entry,
{
if (entry_is_live(entry, 0, 1, 0, &msg)) {
if (n++ == options->NumEntryGuards) {
control_event_guard(entry->nickname, entry->identity, "DEFERRED");
return;
}
}
});
#endif
}
/** Add a new (preferably stable and fast) router to our
* entry_guards list. Return a pointer to the router if we succeed,
* or NULL if we can't find any more suitable entries.
*
* If <b>chosen</b> is defined, use that one, and if it's not
* already in our entry_guards list, put it at the *beginning*.
* Else, put the one we pick at the end of the list. */
static const node_t *
add_an_entry_guard(const node_t *chosen, int reset_status, int prepend)
{
const node_t *node;
entry_guard_t *entry;
if (chosen) {
node = chosen;
entry = is_an_entry_guard(node->identity);
if (entry) {
if (reset_status) {
entry->bad_since = 0;
entry->can_retry = 1;
}
return NULL;
}
} else {
node = choose_good_entry_server(CIRCUIT_PURPOSE_C_GENERAL, NULL);
if (!node)
return NULL;
}
entry = tor_malloc_zero(sizeof(entry_guard_t));
log_info(LD_CIRC, "Chose %s as new entry guard.",
node_describe(node));
strlcpy(entry->nickname, node_get_nickname(node), sizeof(entry->nickname));
memcpy(entry->identity, node->identity, DIGEST_LEN);
/* Choose expiry time smudged over the past month. The goal here
* is to a) spread out when Tor clients rotate their guards, so they
* don't all select them on the same day, and b) avoid leaving a
* precise timestamp in the state file about when we first picked
* this guard. For details, see the Jan 2010 or-dev thread. */
entry->chosen_on_date = time(NULL) - crypto_rand_int(3600*24*30);
entry->chosen_by_version = tor_strdup(VERSION);
if (prepend)
smartlist_insert(entry_guards, 0, entry);
else
smartlist_add(entry_guards, entry);
control_event_guard(entry->nickname, entry->identity, "NEW");
control_event_guard_deferred();
log_entry_guards(LOG_INFO);
return node;
}
/** If the use of entry guards is configured, choose more entry guards
* until we have enough in the list. */
static void
pick_entry_guards(const or_options_t *options)
{
int changed = 0;
tor_assert(entry_guards);
while (num_live_entry_guards() < options->NumEntryGuards) {
if (!add_an_entry_guard(NULL, 0, 0))
break;
changed = 1;
}
if (changed)
entry_guards_changed();
}
/** How long (in seconds) do we allow an entry guard to be nonfunctional,
* unlisted, excluded, or otherwise nonusable before we give up on it? */
#define ENTRY_GUARD_REMOVE_AFTER (30*24*60*60)
/** Release all storage held by <b>e</b>. */
static void
entry_guard_free(entry_guard_t *e)
{
if (!e)
return;
tor_free(e->chosen_by_version);
tor_free(e);
}
/** Remove any entry guard which was selected by an unknown version of Tor,
* or which was selected by a version of Tor that's known to select
* entry guards badly. */
static int
remove_obsolete_entry_guards(time_t now)
{
int changed = 0, i;
for (i = 0; i < smartlist_len(entry_guards); ++i) {
entry_guard_t *entry = smartlist_get(entry_guards, i);
const char *ver = entry->chosen_by_version;
const char *msg = NULL;
tor_version_t v;
int version_is_bad = 0, date_is_bad = 0;
if (!ver) {
msg = "does not say what version of Tor it was selected by";
version_is_bad = 1;
} else if (tor_version_parse(ver, &v)) {
msg = "does not seem to be from any recognized version of Tor";
version_is_bad = 1;
} else {
size_t len = strlen(ver)+5;
char *tor_ver = tor_malloc(len);
tor_snprintf(tor_ver, len, "Tor %s", ver);
if ((tor_version_as_new_as(tor_ver, "0.1.0.10-alpha") &&
!tor_version_as_new_as(tor_ver, "0.1.2.16-dev")) ||
(tor_version_as_new_as(tor_ver, "0.2.0.0-alpha") &&
!tor_version_as_new_as(tor_ver, "0.2.0.6-alpha")) ||
/* above are bug 440; below are bug 1217 */
(tor_version_as_new_as(tor_ver, "0.2.1.3-alpha") &&
!tor_version_as_new_as(tor_ver, "0.2.1.23")) ||
(tor_version_as_new_as(tor_ver, "0.2.2.0-alpha") &&
!tor_version_as_new_as(tor_ver, "0.2.2.7-alpha"))) {
msg = "was selected without regard for guard bandwidth";
version_is_bad = 1;
}
tor_free(tor_ver);
}
if (!version_is_bad && entry->chosen_on_date + 3600*24*60 < now) {
/* It's been 2 months since the date listed in our state file. */
msg = "was selected several months ago";
date_is_bad = 1;
}
if (version_is_bad || date_is_bad) { /* we need to drop it */
char dbuf[HEX_DIGEST_LEN+1];
tor_assert(msg);
base16_encode(dbuf, sizeof(dbuf), entry->identity, DIGEST_LEN);
log_fn(version_is_bad ? LOG_NOTICE : LOG_INFO, LD_CIRC,
"Entry guard '%s' (%s) %s. (Version=%s.) Replacing it.",
entry->nickname, dbuf, msg, ver?escaped(ver):"none");
control_event_guard(entry->nickname, entry->identity, "DROPPED");
entry_guard_free(entry);
smartlist_del_keeporder(entry_guards, i--);
log_entry_guards(LOG_INFO);
changed = 1;
}
}
return changed ? 1 : 0;
}
/** Remove all entry guards that have been down or unlisted for so
* long that we don't think they'll come up again. Return 1 if we
* removed any, or 0 if we did nothing. */
static int
remove_dead_entry_guards(time_t now)
{
char dbuf[HEX_DIGEST_LEN+1];
char tbuf[ISO_TIME_LEN+1];
int i;
int changed = 0;
for (i = 0; i < smartlist_len(entry_guards); ) {
entry_guard_t *entry = smartlist_get(entry_guards, i);
if (entry->bad_since &&
entry->bad_since + ENTRY_GUARD_REMOVE_AFTER < now) {
base16_encode(dbuf, sizeof(dbuf), entry->identity, DIGEST_LEN);
format_local_iso_time(tbuf, entry->bad_since);
log_info(LD_CIRC, "Entry guard '%s' (%s) has been down or unlisted "
"since %s local time; removing.",
entry->nickname, dbuf, tbuf);
control_event_guard(entry->nickname, entry->identity, "DROPPED");
entry_guard_free(entry);
smartlist_del_keeporder(entry_guards, i);
log_entry_guards(LOG_INFO);
changed = 1;
} else
++i;
}
return changed ? 1 : 0;
}
/** A new directory or router-status has arrived; update the down/listed
* status of the entry guards.
*
* An entry is 'down' if the directory lists it as nonrunning.
* An entry is 'unlisted' if the directory doesn't include it.
*
* Don't call this on startup; only on a fresh download. Otherwise we'll
* think that things are unlisted.
*/
void
entry_guards_compute_status(const or_options_t *options, time_t now)
{
int changed = 0;
digestmap_t *reasons;
if (! entry_guards)
return;
if (options->EntryNodes) /* reshuffle the entry guard list if needed */
entry_nodes_should_be_added();
reasons = digestmap_new();
SMARTLIST_FOREACH_BEGIN(entry_guards, entry_guard_t *, entry)
{
const node_t *r = node_get_by_id(entry->identity);
const char *reason = NULL;
if (entry_guard_set_status(entry, r, now, options, &reason))
changed = 1;
if (entry->bad_since)
tor_assert(reason);
if (reason)
digestmap_set(reasons, entry->identity, (char*)reason);
}
SMARTLIST_FOREACH_END(entry);
if (remove_dead_entry_guards(now))
changed = 1;
if (changed) {
SMARTLIST_FOREACH_BEGIN(entry_guards, entry_guard_t *, entry) {
const char *reason = digestmap_get(reasons, entry->identity);
const char *live_msg = "";
const node_t *r = entry_is_live(entry, 0, 1, 0, &live_msg);
log_info(LD_CIRC, "Summary: Entry %s [%s] is %s, %s%s%s, and %s%s.",
entry->nickname,
hex_str(entry->identity, DIGEST_LEN),
entry->unreachable_since ? "unreachable" : "reachable",
entry->bad_since ? "unusable" : "usable",
reason ? ", ": "",
reason ? reason : "",
r ? "live" : "not live / ",
r ? "" : live_msg);
} SMARTLIST_FOREACH_END(entry);
log_info(LD_CIRC, " (%d/%d entry guards are usable/new)",
num_live_entry_guards(), smartlist_len(entry_guards));
log_entry_guards(LOG_INFO);
entry_guards_changed();
}
digestmap_free(reasons, NULL);
}
/** Called when a connection to an OR with the identity digest <b>digest</b>
* is established (<b>succeeded</b>==1) or has failed (<b>succeeded</b>==0).
* If the OR is an entry, change that entry's up/down status.
* Return 0 normally, or -1 if we want to tear down the new connection.
*
* If <b>mark_relay_status</b>, also call router_set_status() on this
* relay.
*
* XXX023 change succeeded and mark_relay_status into 'int flags'.
*/
int
entry_guard_register_connect_status(const char *digest, int succeeded,
int mark_relay_status, time_t now)
{
int changed = 0;
int refuse_conn = 0;
int first_contact = 0;
entry_guard_t *entry = NULL;
int idx = -1;
char buf[HEX_DIGEST_LEN+1];
if (! entry_guards)
return 0;
SMARTLIST_FOREACH(entry_guards, entry_guard_t *, e,
{
if (tor_memeq(e->identity, digest, DIGEST_LEN)) {
entry = e;
idx = e_sl_idx;
break;
}
});
if (!entry)
return 0;
base16_encode(buf, sizeof(buf), entry->identity, DIGEST_LEN);
if (succeeded) {
if (entry->unreachable_since) {
log_info(LD_CIRC, "Entry guard '%s' (%s) is now reachable again. Good.",
entry->nickname, buf);
entry->can_retry = 0;
entry->unreachable_since = 0;
entry->last_attempted = now;
control_event_guard(entry->nickname, entry->identity, "UP");
changed = 1;
}
if (!entry->made_contact) {
entry->made_contact = 1;
first_contact = changed = 1;
}
} else { /* ! succeeded */
if (!entry->made_contact) {
/* We've never connected to this one. */
log_info(LD_CIRC,
"Connection to never-contacted entry guard '%s' (%s) failed. "
"Removing from the list. %d/%d entry guards usable/new.",
entry->nickname, buf,
num_live_entry_guards()-1, smartlist_len(entry_guards)-1);
control_event_guard(entry->nickname, entry->identity, "DROPPED");
entry_guard_free(entry);
smartlist_del_keeporder(entry_guards, idx);
log_entry_guards(LOG_INFO);
changed = 1;
} else if (!entry->unreachable_since) {
log_info(LD_CIRC, "Unable to connect to entry guard '%s' (%s). "
"Marking as unreachable.", entry->nickname, buf);
entry->unreachable_since = entry->last_attempted = now;
control_event_guard(entry->nickname, entry->identity, "DOWN");
changed = 1;
entry->can_retry = 0; /* We gave it an early chance; no good. */
} else {
char tbuf[ISO_TIME_LEN+1];
format_iso_time(tbuf, entry->unreachable_since);
log_debug(LD_CIRC, "Failed to connect to unreachable entry guard "
"'%s' (%s). It has been unreachable since %s.",
entry->nickname, buf, tbuf);
entry->last_attempted = now;
entry->can_retry = 0; /* We gave it an early chance; no good. */
}
}
/* if the caller asked us to, also update the is_running flags for this
* relay */
if (mark_relay_status)
router_set_status(digest, succeeded);
if (first_contact) {
/* We've just added a new long-term entry guard. Perhaps the network just
* came back? We should give our earlier entries another try too,
* and close this connection so we don't use it before we've given
* the others a shot. */
SMARTLIST_FOREACH(entry_guards, entry_guard_t *, e, {
if (e == entry)
break;
if (e->made_contact) {
const char *msg;
const node_t *r = entry_is_live(e, 0, 1, 1, &msg);
if (r && e->unreachable_since) {
refuse_conn = 1;
e->can_retry = 1;
}
}
});
if (refuse_conn) {
log_info(LD_CIRC,
"Connected to new entry guard '%s' (%s). Marking earlier "
"entry guards up. %d/%d entry guards usable/new.",
entry->nickname, buf,
num_live_entry_guards(), smartlist_len(entry_guards));
log_entry_guards(LOG_INFO);
changed = 1;
}
}
if (changed)
entry_guards_changed();
return refuse_conn ? -1 : 0;
}
/** When we try to choose an entry guard, should we parse and add
* config's EntryNodes first? */
static int should_add_entry_nodes = 0;
/** Called when the value of EntryNodes changes in our configuration. */
void
entry_nodes_should_be_added(void)
{
log_info(LD_CIRC, "EntryNodes config option set. Putting configured "
"relays at the front of the entry guard list.");
should_add_entry_nodes = 1;
}
/** Adjust the entry guards list so that it only contains entries from
* EntryNodes, adding new entries from EntryNodes to the list as needed. */
static void
entry_guards_set_from_config(const or_options_t *options)
{
smartlist_t *entry_nodes, *worse_entry_nodes, *entry_fps;
smartlist_t *old_entry_guards_on_list, *old_entry_guards_not_on_list;
tor_assert(entry_guards);
should_add_entry_nodes = 0;
if (!options->EntryNodes) {
/* It's possible that a controller set EntryNodes, thus making
* should_add_entry_nodes set, then cleared it again, all before the
* call to choose_random_entry() that triggered us. If so, just return.
*/
return;
}
{
char *string = routerset_to_string(options->EntryNodes);
log_info(LD_CIRC,"Adding configured EntryNodes '%s'.", string);
tor_free(string);
}
entry_nodes = smartlist_create();
worse_entry_nodes = smartlist_create();
entry_fps = smartlist_create();
old_entry_guards_on_list = smartlist_create();
old_entry_guards_not_on_list = smartlist_create();
/* Split entry guards into those on the list and those not. */
routerset_get_all_nodes(entry_nodes, options->EntryNodes,
options->ExcludeNodes, 0);
SMARTLIST_FOREACH(entry_nodes, const node_t *,node,
smartlist_add(entry_fps, (void*)node->identity));
SMARTLIST_FOREACH(entry_guards, entry_guard_t *, e, {
if (smartlist_digest_isin(entry_fps, e->identity))
smartlist_add(old_entry_guards_on_list, e);
else
smartlist_add(old_entry_guards_not_on_list, e);
});
/* Remove all currently configured guard nodes, excluded nodes, unreachable
* nodes, or non-Guard nodes from entry_nodes. */
SMARTLIST_FOREACH_BEGIN(entry_nodes, const node_t *, node) {
if (is_an_entry_guard(node->identity)) {
SMARTLIST_DEL_CURRENT(entry_nodes, node);
continue;
} else if (routerset_contains_node(options->ExcludeNodes, node)) {
SMARTLIST_DEL_CURRENT(entry_nodes, node);
continue;
} else if (!fascist_firewall_allows_node(node)) {
SMARTLIST_DEL_CURRENT(entry_nodes, node);
continue;
} else if (! node->is_possible_guard) {
smartlist_add(worse_entry_nodes, (node_t*)node);
SMARTLIST_DEL_CURRENT(entry_nodes, node);
}
} SMARTLIST_FOREACH_END(node);
/* Now build the new entry_guards list. */
smartlist_clear(entry_guards);
/* First, the previously configured guards that are in EntryNodes. */
smartlist_add_all(entry_guards, old_entry_guards_on_list);
/* Next, scramble the rest of EntryNodes, putting the guards first. */
smartlist_shuffle(entry_nodes);
smartlist_shuffle(worse_entry_nodes);
smartlist_add_all(entry_nodes, worse_entry_nodes);
/* Next, the rest of EntryNodes */
SMARTLIST_FOREACH_BEGIN(entry_nodes, const node_t *, node) {
add_an_entry_guard(node, 0, 0);
if (smartlist_len(entry_guards) > options->NumEntryGuards * 10)
break;
} SMARTLIST_FOREACH_END(node);
log_notice(LD_GENERAL, "%d entries in guards", smartlist_len(entry_guards));
/* Finally, free the remaining previously configured guards that are not in
* EntryNodes. */
SMARTLIST_FOREACH(old_entry_guards_not_on_list, entry_guard_t *, e,
entry_guard_free(e));
smartlist_free(entry_nodes);
smartlist_free(worse_entry_nodes);
smartlist_free(entry_fps);
smartlist_free(old_entry_guards_on_list);
smartlist_free(old_entry_guards_not_on_list);
entry_guards_changed();
}
/** Return 0 if we're fine adding arbitrary routers out of the
* directory to our entry guard list, or return 1 if we have a
* list already and we must stick to it.
*/
int
entry_list_is_constrained(const or_options_t *options)
{
if (options->EntryNodes)
return 1;
if (options->UseBridges)
return 1;
return 0;
}
/** Pick a live (up and listed) entry guard from entry_guards. If
* <b>state</b> is non-NULL, this is for a specific circuit --
* make sure not to pick this circuit's exit or any node in the
* exit's family. If <b>state</b> is NULL, we're looking for a random
* guard (likely a bridge). */
const node_t *
choose_random_entry(cpath_build_state_t *state)
{
const or_options_t *options = get_options();
smartlist_t *live_entry_guards = smartlist_create();
smartlist_t *exit_family = smartlist_create();
const node_t *chosen_exit =
state?build_state_get_exit_node(state) : NULL;
const node_t *node = NULL;
int need_uptime = state ? state->need_uptime : 0;
int need_capacity = state ? state->need_capacity : 0;
int preferred_min, consider_exit_family = 0;
if (chosen_exit) {
nodelist_add_node_and_family(exit_family, chosen_exit);
consider_exit_family = 1;
}
if (!entry_guards)
entry_guards = smartlist_create();
if (should_add_entry_nodes)
entry_guards_set_from_config(options);
if (!entry_list_is_constrained(options) &&
smartlist_len(entry_guards) < options->NumEntryGuards)
pick_entry_guards(options);
retry:
smartlist_clear(live_entry_guards);
SMARTLIST_FOREACH_BEGIN(entry_guards, entry_guard_t *, entry) {
const char *msg;
node = entry_is_live(entry, need_uptime, need_capacity, 0, &msg);
if (!node)
continue; /* down, no point */
if (node == chosen_exit)
continue; /* don't pick the same node for entry and exit */
if (consider_exit_family && smartlist_isin(exit_family, node))
continue; /* avoid relays that are family members of our exit */
#if 0 /* since EntryNodes is always strict now, this clause is moot */
if (options->EntryNodes &&
!routerset_contains_node(options->EntryNodes, node)) {
/* We've come to the end of our preferred entry nodes. */
if (smartlist_len(live_entry_guards))
goto choose_and_finish; /* only choose from the ones we like */
if (options->StrictNodes) {
/* in theory this case should never happen, since
* entry_guards_set_from_config() drops unwanted relays */
tor_fragile_assert();
} else {
log_info(LD_CIRC,
"No relays from EntryNodes available. Using others.");
}
}
#endif
smartlist_add(live_entry_guards, (void*)node);
if (!entry->made_contact) {
/* Always start with the first not-yet-contacted entry
* guard. Otherwise we might add several new ones, pick
* the second new one, and now we've expanded our entry
* guard list without needing to. */
goto choose_and_finish;
}
if (smartlist_len(live_entry_guards) >= options->NumEntryGuards)
break; /* we have enough */
} SMARTLIST_FOREACH_END(entry);
if (entry_list_is_constrained(options)) {
/* If we prefer the entry nodes we've got, and we have at least
* one choice, that's great. Use it. */
preferred_min = 1;
} else {
/* Try to have at least 2 choices available. This way we don't
* get stuck with a single live-but-crummy entry and just keep
* using him.
* (We might get 2 live-but-crummy entry guards, but so be it.) */
preferred_min = 2;
}
if (smartlist_len(live_entry_guards) < preferred_min) {
if (!entry_list_is_constrained(options)) {
/* still no? try adding a new entry then */
/* XXX if guard doesn't imply fast and stable, then we need
* to tell add_an_entry_guard below what we want, or it might
* be a long time til we get it. -RD */
node = add_an_entry_guard(NULL, 0, 0);
if (node) {
entry_guards_changed();
/* XXX we start over here in case the new node we added shares
* a family with our exit node. There's a chance that we'll just
* load up on entry guards here, if the network we're using is
* one big family. Perhaps we should teach add_an_entry_guard()
* to understand nodes-to-avoid-if-possible? -RD */
goto retry;
}
}
if (!node && need_uptime) {
need_uptime = 0; /* try without that requirement */
goto retry;
}
if (!node && need_capacity) {
/* still no? last attempt, try without requiring capacity */
need_capacity = 0;
goto retry;
}
#if 0
/* Removing this retry logic: if we only allow one exit, and it is in the
same family as all our entries, then we are just plain not going to win
here. */
if (!node && entry_list_is_constrained(options) && consider_exit_family) {
/* still no? if we're using bridges or have strictentrynodes
* set, and our chosen exit is in the same family as all our
* bridges/entry guards, then be flexible about families. */
consider_exit_family = 0;
goto retry;
}
#endif
/* live_entry_guards may be empty below. Oh well, we tried. */
}
choose_and_finish:
if (entry_list_is_constrained(options)) {
/* We need to weight by bandwidth, because our bridges or entryguards
* were not already selected proportional to their bandwidth. */
node = node_sl_choose_by_bandwidth(live_entry_guards, WEIGHT_FOR_GUARD);
} else {
/* We choose uniformly at random here, because choose_good_entry_server()
* already weights its choices by bandwidth, so we don't want to
* *double*-weight our guard selection. */
node = smartlist_choose(live_entry_guards);
}
smartlist_free(live_entry_guards);
smartlist_free(exit_family);
return node;
}
/** Parse <b>state</b> and learn about the entry guards it describes.
* If <b>set</b> is true, and there are no errors, replace the global
* entry_list with what we find.
* On success, return 0. On failure, alloc into *<b>msg</b> a string
* describing the error, and return -1.
*/
int
entry_guards_parse_state(or_state_t *state, int set, char **msg)
{
entry_guard_t *node = NULL;
smartlist_t *new_entry_guards = smartlist_create();
config_line_t *line;
time_t now = time(NULL);
const char *state_version = state->TorVersion;
digestmap_t *added_by = digestmap_new();
*msg = NULL;
for (line = state->EntryGuards; line; line = line->next) {
if (!strcasecmp(line->key, "EntryGuard")) {
smartlist_t *args = smartlist_create();
node = tor_malloc_zero(sizeof(entry_guard_t));
/* all entry guards on disk have been contacted */
node->made_contact = 1;
smartlist_add(new_entry_guards, node);
smartlist_split_string(args, line->value, " ",
SPLIT_SKIP_SPACE|SPLIT_IGNORE_BLANK, 0);
if (smartlist_len(args)<2) {
*msg = tor_strdup("Unable to parse entry nodes: "
"Too few arguments to EntryGuard");
} else if (!is_legal_nickname(smartlist_get(args,0))) {
*msg = tor_strdup("Unable to parse entry nodes: "
"Bad nickname for EntryGuard");
} else {
strlcpy(node->nickname, smartlist_get(args,0), MAX_NICKNAME_LEN+1);
if (base16_decode(node->identity, DIGEST_LEN, smartlist_get(args,1),
strlen(smartlist_get(args,1)))<0) {
*msg = tor_strdup("Unable to parse entry nodes: "
"Bad hex digest for EntryGuard");
}
}
SMARTLIST_FOREACH(args, char*, cp, tor_free(cp));
smartlist_free(args);
if (*msg)
break;
} else if (!strcasecmp(line->key, "EntryGuardDownSince") ||
!strcasecmp(line->key, "EntryGuardUnlistedSince")) {
time_t when;
time_t last_try = 0;
if (!node) {
*msg = tor_strdup("Unable to parse entry nodes: "
"EntryGuardDownSince/UnlistedSince without EntryGuard");
break;
}
if (parse_iso_time(line->value, &when)<0) {
*msg = tor_strdup("Unable to parse entry nodes: "
"Bad time in EntryGuardDownSince/UnlistedSince");
break;
}
if (when > now) {
/* It's a bad idea to believe info in the future: you can wind
* up with timeouts that aren't allowed to happen for years. */
continue;
}
if (strlen(line->value) >= ISO_TIME_LEN+ISO_TIME_LEN+1) {
/* ignore failure */
(void) parse_iso_time(line->value+ISO_TIME_LEN+1, &last_try);
}
if (!strcasecmp(line->key, "EntryGuardDownSince")) {
node->unreachable_since = when;
node->last_attempted = last_try;
} else {
node->bad_since = when;
}
} else if (!strcasecmp(line->key, "EntryGuardAddedBy")) {
char d[DIGEST_LEN];
/* format is digest version date */
if (strlen(line->value) < HEX_DIGEST_LEN+1+1+1+ISO_TIME_LEN) {
log_warn(LD_BUG, "EntryGuardAddedBy line is not long enough.");
continue;
}
if (base16_decode(d, sizeof(d), line->value, HEX_DIGEST_LEN)<0 ||
line->value[HEX_DIGEST_LEN] != ' ') {
log_warn(LD_BUG, "EntryGuardAddedBy line %s does not begin with "
"hex digest", escaped(line->value));
continue;
}
digestmap_set(added_by, d, tor_strdup(line->value+HEX_DIGEST_LEN+1));
} else {
log_warn(LD_BUG, "Unexpected key %s", line->key);
}
}
SMARTLIST_FOREACH(new_entry_guards, entry_guard_t *, e,
{
char *sp;
char *val = digestmap_get(added_by, e->identity);
if (val && (sp = strchr(val, ' '))) {
time_t when;
*sp++ = '\0';
if (parse_iso_time(sp, &when)<0) {
log_warn(LD_BUG, "Can't read time %s in EntryGuardAddedBy", sp);
} else {
e->chosen_by_version = tor_strdup(val);
e->chosen_on_date = when;
}
} else {
if (state_version) {
e->chosen_by_version = tor_strdup(state_version);
e->chosen_on_date = time(NULL) - crypto_rand_int(3600*24*30);
}
}
});
if (*msg || !set) {
SMARTLIST_FOREACH(new_entry_guards, entry_guard_t *, e,
entry_guard_free(e));
smartlist_free(new_entry_guards);
} else { /* !err && set */
if (entry_guards) {
SMARTLIST_FOREACH(entry_guards, entry_guard_t *, e,
entry_guard_free(e));
smartlist_free(entry_guards);
}
entry_guards = new_entry_guards;
entry_guards_dirty = 0;
/* XXX023 hand new_entry_guards to this func, and move it up a
* few lines, so we don't have to re-dirty it */
if (remove_obsolete_entry_guards(now))
entry_guards_dirty = 1;
}
digestmap_free(added_by, _tor_free);
return *msg ? -1 : 0;
}
/** Our list of entry guards has changed, or some element of one
* of our entry guards has changed. Write the changes to disk within
* the next few minutes.
*/
static void
entry_guards_changed(void)
{
time_t when;
entry_guards_dirty = 1;
/* or_state_save() will call entry_guards_update_state(). */
when = get_options()->AvoidDiskWrites ? time(NULL) + 3600 : time(NULL)+600;
or_state_mark_dirty(get_or_state(), when);
}
/** If the entry guard info has not changed, do nothing and return.
* Otherwise, free the EntryGuards piece of <b>state</b> and create
* a new one out of the global entry_guards list, and then mark
* <b>state</b> dirty so it will get saved to disk.
*/
void
entry_guards_update_state(or_state_t *state)
{
config_line_t **next, *line;
if (! entry_guards_dirty)
return;
config_free_lines(state->EntryGuards);
next = &state->EntryGuards;
*next = NULL;
if (!entry_guards)
entry_guards = smartlist_create();
SMARTLIST_FOREACH(entry_guards, entry_guard_t *, e,
{
char dbuf[HEX_DIGEST_LEN+1];
if (!e->made_contact)
continue; /* don't write this one to disk */
*next = line = tor_malloc_zero(sizeof(config_line_t));
line->key = tor_strdup("EntryGuard");
line->value = tor_malloc(HEX_DIGEST_LEN+MAX_NICKNAME_LEN+2);
base16_encode(dbuf, sizeof(dbuf), e->identity, DIGEST_LEN);
tor_snprintf(line->value,HEX_DIGEST_LEN+MAX_NICKNAME_LEN+2,
"%s %s", e->nickname, dbuf);
next = &(line->next);
if (e->unreachable_since) {
*next = line = tor_malloc_zero(sizeof(config_line_t));
line->key = tor_strdup("EntryGuardDownSince");
line->value = tor_malloc(ISO_TIME_LEN+1+ISO_TIME_LEN+1);
format_iso_time(line->value, e->unreachable_since);
if (e->last_attempted) {
line->value[ISO_TIME_LEN] = ' ';
format_iso_time(line->value+ISO_TIME_LEN+1, e->last_attempted);
}
next = &(line->next);
}
if (e->bad_since) {
*next = line = tor_malloc_zero(sizeof(config_line_t));
line->key = tor_strdup("EntryGuardUnlistedSince");
line->value = tor_malloc(ISO_TIME_LEN+1);
format_iso_time(line->value, e->bad_since);
next = &(line->next);
}
if (e->chosen_on_date && e->chosen_by_version &&
!strchr(e->chosen_by_version, ' ')) {
char d[HEX_DIGEST_LEN+1];
char t[ISO_TIME_LEN+1];
size_t val_len;
*next = line = tor_malloc_zero(sizeof(config_line_t));
line->key = tor_strdup("EntryGuardAddedBy");
val_len = (HEX_DIGEST_LEN+1+strlen(e->chosen_by_version)
+1+ISO_TIME_LEN+1);
line->value = tor_malloc(val_len);
base16_encode(d, sizeof(d), e->identity, DIGEST_LEN);
format_iso_time(t, e->chosen_on_date);
tor_snprintf(line->value, val_len, "%s %s %s",
d, e->chosen_by_version, t);
next = &(line->next);
}
});
if (!get_options()->AvoidDiskWrites)
or_state_mark_dirty(get_or_state(), 0);
entry_guards_dirty = 0;
}
/** If <b>question</b> is the string "entry-guards", then dump
* to *<b>answer</b> a newly allocated string describing all of
* the nodes in the global entry_guards list. See control-spec.txt
* for details.
* For backward compatibility, we also handle the string "helper-nodes".
* */
int
getinfo_helper_entry_guards(control_connection_t *conn,
const char *question, char **answer,
const char **errmsg)
{
(void) conn;
(void) errmsg;
if (!strcmp(question,"entry-guards") ||
!strcmp(question,"helper-nodes")) {
smartlist_t *sl = smartlist_create();
char tbuf[ISO_TIME_LEN+1];
char nbuf[MAX_VERBOSE_NICKNAME_LEN+1];
if (!entry_guards)
entry_guards = smartlist_create();
SMARTLIST_FOREACH_BEGIN(entry_guards, entry_guard_t *, e) {
size_t len = MAX_VERBOSE_NICKNAME_LEN+ISO_TIME_LEN+32;
char *c = tor_malloc(len);
const char *status = NULL;
time_t when = 0;
const node_t *node;
if (!e->made_contact) {
status = "never-connected";
} else if (e->bad_since) {
when = e->bad_since;
status = "unusable";
} else {
status = "up";
}
node = node_get_by_id(e->identity);
if (node) {
node_get_verbose_nickname(node, nbuf);
} else {
nbuf[0] = '$';
base16_encode(nbuf+1, sizeof(nbuf)-1, e->identity, DIGEST_LEN);
/* e->nickname field is not very reliable if we don't know about
* this router any longer; don't include it. */
}
if (when) {
format_iso_time(tbuf, when);
tor_snprintf(c, len, "%s %s %s\n", nbuf, status, tbuf);
} else {
tor_snprintf(c, len, "%s %s\n", nbuf, status);
}
smartlist_add(sl, c);
} SMARTLIST_FOREACH_END(e);
*answer = smartlist_join_strings(sl, "", 0, NULL);
SMARTLIST_FOREACH(sl, char *, c, tor_free(c));
smartlist_free(sl);
}
return 0;
}
/** A list of configured bridges. Whenever we actually get a descriptor
* for one, we add it as an entry guard. Note that the order of bridges
* in this list does not necessarily correspond to the order of bridges
* in the torrc. */
static smartlist_t *bridge_list = NULL;
/** Mark every entry of the bridge list to be removed on our next call to
* sweep_bridge_list unless it has first been un-marked. */
void
mark_bridge_list(void)
{
if (!bridge_list)
bridge_list = smartlist_create();
SMARTLIST_FOREACH(bridge_list, bridge_info_t *, b,
b->marked_for_removal = 1);
}
/** Remove every entry of the bridge list that was marked with
* mark_bridge_list if it has not subsequently been un-marked. */
void
sweep_bridge_list(void)
{
if (!bridge_list)
bridge_list = smartlist_create();
SMARTLIST_FOREACH_BEGIN(bridge_list, bridge_info_t *, b) {
if (b->marked_for_removal) {
SMARTLIST_DEL_CURRENT(bridge_list, b);
bridge_free(b);
}
} SMARTLIST_FOREACH_END(b);
}
/** Initialize the bridge list to empty, creating it if needed. */
static void
clear_bridge_list(void)
{
if (!bridge_list)
bridge_list = smartlist_create();
SMARTLIST_FOREACH(bridge_list, bridge_info_t *, b, bridge_free(b));
smartlist_clear(bridge_list);
}
/** Free the bridge <b>bridge</b>. */
static void
bridge_free(bridge_info_t *bridge)
{
if (!bridge)
return;
tor_free(bridge->transport_name);
tor_free(bridge);
}
/** A list of pluggable transports found in torrc. */
static smartlist_t *transport_list = NULL;
/** Initialize the pluggable transports list to empty, creating it if
* needed. */
void
clear_transport_list(void)
{
if (!transport_list)
transport_list = smartlist_create();
SMARTLIST_FOREACH(transport_list, transport_t *, t, transport_free(t));
smartlist_clear(transport_list);
}
/** Free the pluggable transport struct <b>transport</b>. */
static void
transport_free(transport_t *transport)
{
if (!transport)
return;
tor_free(transport->name);
tor_free(transport);
}
/** Returns the transport in our transport list that has the name <b>name</b>.
* Else returns NULL. */
static const transport_t *
transport_get_by_name(const char *name)
{
tor_assert(name);
if (!transport_list)
return NULL;
SMARTLIST_FOREACH_BEGIN(transport_list, const transport_t *, transport) {
if (!strcmp(transport->name, name))
return transport;
} SMARTLIST_FOREACH_END(transport);
return NULL;
}
/** Remember a new pluggable transport proxy at <b>addr</b>:<b>port</b>.
* <b>name</b> is set to the name of the protocol this proxy uses.
* <b>socks_ver</b> is set to the SOCKS version of the proxy.
*
* Returns 0 on success, -1 on fail. */
int
transport_add_from_config(const tor_addr_t *addr, uint16_t port,
const char *name, int socks_ver)
{
transport_t *t;
if (transport_get_by_name(name)) { /* check for duplicate names */
log_warn(LD_CONFIG, "More than one transport has '%s' as "
"its name.", name);
return -1;
}
t = tor_malloc_zero(sizeof(transport_t));
tor_addr_copy(&t->addr, addr);
t->port = port;
t->name = tor_strdup(name);
t->socks_version = socks_ver;
if (!transport_list)
transport_list = smartlist_create();
smartlist_add(transport_list, t);
return 0;
}
/** Warns the user of possible pluggable transport misconfiguration. */
void
validate_pluggable_transports_config(void)
{
if (bridge_list) {
SMARTLIST_FOREACH_BEGIN(bridge_list, bridge_info_t *, b) {
/* Skip bridges without transports. */
if (!b->transport_name)
continue;
/* See if the user has Bridges that specify nonexistent
pluggable transports. We should warn the user in such case,
since it's probably misconfiguration. */
if (!transport_get_by_name(b->transport_name))
log_warn(LD_CONFIG, "You have a Bridge line using the %s "
"pluggable transport, but there doesn't seem to be a "
"corresponding ClientTransportPlugin line.",
b->transport_name);
} SMARTLIST_FOREACH_END(b);
}
}
/** Return a bridge pointer if <b>ri</b> is one of our known bridges
* (either by comparing keys if possible, else by comparing addr/port).
* Else return NULL. */
static bridge_info_t *
get_configured_bridge_by_addr_port_digest(const tor_addr_t *addr,
uint16_t port,
const char *digest)
{
if (!bridge_list)
return NULL;
SMARTLIST_FOREACH_BEGIN(bridge_list, bridge_info_t *, bridge)
{
if (tor_digest_is_zero(bridge->identity) &&
!tor_addr_compare(&bridge->addr, addr, CMP_EXACT) &&
bridge->port == port)
return bridge;
if (digest && tor_memeq(bridge->identity, digest, DIGEST_LEN))
return bridge;
}
SMARTLIST_FOREACH_END(bridge);
return NULL;
}
/** Wrapper around get_configured_bridge_by_addr_port_digest() to look
* it up via router descriptor <b>ri</b>. */
static bridge_info_t *
get_configured_bridge_by_routerinfo(const routerinfo_t *ri)
{
tor_addr_t addr;
tor_addr_from_ipv4h(&addr, ri->addr);
return get_configured_bridge_by_addr_port_digest(&addr,
ri->or_port, ri->cache_info.identity_digest);
}
/** Return 1 if <b>ri</b> is one of our known bridges, else 0. */
int
routerinfo_is_a_configured_bridge(const routerinfo_t *ri)
{
return get_configured_bridge_by_routerinfo(ri) ? 1 : 0;
}
/** Return 1 if <b>node</b> is one of our configured bridges, else 0. */
int
node_is_a_configured_bridge(const node_t *node)
{
tor_addr_t addr;
uint16_t orport;
if (!node)
return 0;
if (node_get_addr(node, &addr) < 0)
return 0;
orport = node_get_orport(node);
if (orport == 0)
return 0;
return get_configured_bridge_by_addr_port_digest(
&addr, orport, node->identity) != NULL;
}
/** We made a connection to a router at <b>addr</b>:<b>port</b>
* without knowing its digest. Its digest turned out to be <b>digest</b>.
* If it was a bridge, and we still don't know its digest, record it.
*/
void
learned_router_identity(const tor_addr_t *addr, uint16_t port,
const char *digest)
{
bridge_info_t *bridge =
get_configured_bridge_by_addr_port_digest(addr, port, digest);
if (bridge && tor_digest_is_zero(bridge->identity)) {
memcpy(bridge->identity, digest, DIGEST_LEN);
log_notice(LD_DIR, "Learned fingerprint %s for bridge %s:%d",
hex_str(digest, DIGEST_LEN), fmt_addr(addr), port);
}
}
/** Remember a new bridge at <b>addr</b>:<b>port</b>. If <b>digest</b>
* is set, it tells us the identity key too. If we already had the
* bridge in our list, unmark it, and don't actually add anything new.
* If <b>transport_name</b> is non-NULL - the bridge is associated with a
* pluggable transport - we assign the transport to the bridge. */
void
bridge_add_from_config(const tor_addr_t *addr, uint16_t port,
const char *digest, const char *transport_name)
{
bridge_info_t *b;
if ((b = get_configured_bridge_by_addr_port_digest(addr, port, digest))) {
b->marked_for_removal = 0;
return;
}
b = tor_malloc_zero(sizeof(bridge_info_t));
tor_addr_copy(&b->addr, addr);
b->port = port;
if (digest)
memcpy(b->identity, digest, DIGEST_LEN);
if (transport_name)
b->transport_name = tor_strdup(transport_name);
b->fetch_status.schedule = DL_SCHED_BRIDGE;
if (!bridge_list)
bridge_list = smartlist_create();
smartlist_add(bridge_list, b);
}
/** Return true iff <b>routerset</b> contains the bridge <b>bridge</b>. */
static int
routerset_contains_bridge(const routerset_t *routerset,
const bridge_info_t *bridge)
{
int result;
extend_info_t *extinfo;
tor_assert(bridge);
if (!routerset)
return 0;
extinfo = extend_info_alloc(
NULL, bridge->identity, NULL, &bridge->addr, bridge->port);
result = routerset_contains_extendinfo(routerset, extinfo);
extend_info_free(extinfo);
return result;
}
/** If <b>digest</b> is one of our known bridges, return it. */
static bridge_info_t *
find_bridge_by_digest(const char *digest)
{
SMARTLIST_FOREACH(bridge_list, bridge_info_t *, bridge,
{
if (tor_memeq(bridge->identity, digest, DIGEST_LEN))
return bridge;
});
return NULL;
}
/** If <b>addr</b> and <b>port</b> match the address and port of a
* bridge of ours that uses pluggable transports, place its transport
* in <b>transport</b>.
*
* Return 0 on success (found a transport, or found a bridge with no
* transport, or found no bridge); return -1 if we should be using a
* transport, but the transport could not be found.
*/
int
find_transport_by_bridge_addrport(const tor_addr_t *addr, uint16_t port,
const transport_t **transport)
{
*transport = NULL;
if (!bridge_list)
return 0;
SMARTLIST_FOREACH_BEGIN(bridge_list, const bridge_info_t *, bridge) {
if (tor_addr_eq(&bridge->addr, addr) &&
(bridge->port == port)) { /* bridge matched */
if (bridge->transport_name) { /* it also uses pluggable transports */
*transport = transport_get_by_name(bridge->transport_name);
if (*transport == NULL) { /* it uses pluggable transports, but
the transport could not be found! */
return -1;
}
return 0;
} else { /* bridge matched, but it doesn't use transports. */
break;
}
}
} SMARTLIST_FOREACH_END(bridge);
*transport = NULL;
return 0;
}
/** We need to ask <b>bridge</b> for its server descriptor. */
static void
launch_direct_bridge_descriptor_fetch(bridge_info_t *bridge)
{
char *address;
const or_options_t *options = get_options();
if (connection_get_by_type_addr_port_purpose(
CONN_TYPE_DIR, &bridge->addr, bridge->port,
DIR_PURPOSE_FETCH_SERVERDESC))
return; /* it's already on the way */
address = tor_dup_addr(&bridge->addr);
if (routerset_contains_bridge(options->ExcludeNodes, bridge)) {
download_status_mark_impossible(&bridge->fetch_status);
log_warn(LD_APP, "Not using bridge at %s: it is in ExcludeNodes.",
safe_str_client(fmt_addr(&bridge->addr)));
return;
}
directory_initiate_command(address, &bridge->addr,
bridge->port, 0,
0, /* does not matter */
1, bridge->identity,
DIR_PURPOSE_FETCH_SERVERDESC,
ROUTER_PURPOSE_BRIDGE,
0, "authority.z", NULL, 0, 0);
tor_free(address);
}
/** Fetching the bridge descriptor from the bridge authority returned a
* "not found". Fall back to trying a direct fetch. */
void
retry_bridge_descriptor_fetch_directly(const char *digest)
{
bridge_info_t *bridge = find_bridge_by_digest(digest);
if (!bridge)
return; /* not found? oh well. */
launch_direct_bridge_descriptor_fetch(bridge);
}
/** For each bridge in our list for which we don't currently have a
* descriptor, fetch a new copy of its descriptor -- either directly
* from the bridge or via a bridge authority. */
void
fetch_bridge_descriptors(const or_options_t *options, time_t now)
{
int num_bridge_auths = get_n_authorities(BRIDGE_DIRINFO);
int ask_bridge_directly;
int can_use_bridge_authority;
if (!bridge_list)
return;
SMARTLIST_FOREACH_BEGIN(bridge_list, bridge_info_t *, bridge)
{
if (!download_status_is_ready(&bridge->fetch_status, now,
IMPOSSIBLE_TO_DOWNLOAD))
continue; /* don't bother, no need to retry yet */
if (routerset_contains_bridge(options->ExcludeNodes, bridge)) {
download_status_mark_impossible(&bridge->fetch_status);
log_warn(LD_APP, "Not using bridge at %s: it is in ExcludeNodes.",
safe_str_client(fmt_addr(&bridge->addr)));
continue;
}
/* schedule another fetch as if this one will fail, in case it does */
download_status_failed(&bridge->fetch_status, 0);
can_use_bridge_authority = !tor_digest_is_zero(bridge->identity) &&
num_bridge_auths;
ask_bridge_directly = !can_use_bridge_authority ||
!options->UpdateBridgesFromAuthority;
log_debug(LD_DIR, "ask_bridge_directly=%d (%d, %d, %d)",
ask_bridge_directly, tor_digest_is_zero(bridge->identity),
!options->UpdateBridgesFromAuthority, !num_bridge_auths);
if (ask_bridge_directly &&
!fascist_firewall_allows_address_or(&bridge->addr, bridge->port)) {
log_notice(LD_DIR, "Bridge at '%s:%d' isn't reachable by our "
"firewall policy. %s.", fmt_addr(&bridge->addr),
bridge->port,
can_use_bridge_authority ?
"Asking bridge authority instead" : "Skipping");
if (can_use_bridge_authority)
ask_bridge_directly = 0;
else
continue;
}
if (ask_bridge_directly) {
/* we need to ask the bridge itself for its descriptor. */
launch_direct_bridge_descriptor_fetch(bridge);
} else {
/* We have a digest and we want to ask an authority. We could
* combine all the requests into one, but that may give more
* hints to the bridge authority than we want to give. */
char resource[10 + HEX_DIGEST_LEN];
memcpy(resource, "fp/", 3);
base16_encode(resource+3, HEX_DIGEST_LEN+1,
bridge->identity, DIGEST_LEN);
memcpy(resource+3+HEX_DIGEST_LEN, ".z", 3);
log_info(LD_DIR, "Fetching bridge info '%s' from bridge authority.",
resource);
directory_get_from_dirserver(DIR_PURPOSE_FETCH_SERVERDESC,
ROUTER_PURPOSE_BRIDGE, resource, 0);
}
}
SMARTLIST_FOREACH_END(bridge);
}
/** If our <b>bridge</b> is configured to be a different address than
* the bridge gives in <b>node</b>, rewrite the routerinfo
* we received to use the address we meant to use. Now we handle
* multihomed bridges better.
*/
static void
rewrite_node_address_for_bridge(const bridge_info_t *bridge, node_t *node)
{
/* XXXX move this function. */
/* XXXX overridden addresses should really live in the node_t, so that the
* routerinfo_t and the microdesc_t can be immutable. But we can only
* do that safely if we know that no function that connects to an OR
* does so through an address from any source other than node_get_addr().
*/
tor_addr_t addr;
if (node->ri) {
routerinfo_t *ri = node->ri;
tor_addr_from_ipv4h(&addr, ri->addr);
if (!tor_addr_compare(&bridge->addr, &addr, CMP_EXACT) &&
bridge->port == ri->or_port) {
/* they match, so no need to do anything */
} else {
ri->addr = tor_addr_to_ipv4h(&bridge->addr);
tor_free(ri->address);
ri->address = tor_dup_ip(ri->addr);
ri->or_port = bridge->port;
log_info(LD_DIR,
"Adjusted bridge routerinfo for '%s' to match configured "
"address %s:%d.",
ri->nickname, ri->address, ri->or_port);
}
}
if (node->rs) {
routerstatus_t *rs = node->rs;
tor_addr_from_ipv4h(&addr, rs->addr);
if (!tor_addr_compare(&bridge->addr, &addr, CMP_EXACT) &&
bridge->port == rs->or_port) {
/* they match, so no need to do anything */
} else {
rs->addr = tor_addr_to_ipv4h(&bridge->addr);
rs->or_port = bridge->port;
log_info(LD_DIR,
"Adjusted bridge routerstatus for '%s' to match "
"configured address %s:%d.",
rs->nickname, fmt_addr(&bridge->addr), rs->or_port);
}
}
}
/** We just learned a descriptor for a bridge. See if that
* digest is in our entry guard list, and add it if not. */
void
learned_bridge_descriptor(routerinfo_t *ri, int from_cache)
{
tor_assert(ri);
tor_assert(ri->purpose == ROUTER_PURPOSE_BRIDGE);
if (get_options()->UseBridges) {
int first = !any_bridge_descriptors_known();
bridge_info_t *bridge = get_configured_bridge_by_routerinfo(ri);
time_t now = time(NULL);
router_set_status(ri->cache_info.identity_digest, 1);
if (bridge) { /* if we actually want to use this one */
node_t *node;
/* it's here; schedule its re-fetch for a long time from now. */
if (!from_cache)
download_status_reset(&bridge->fetch_status);
node = node_get_mutable_by_id(ri->cache_info.identity_digest);
tor_assert(node);
rewrite_node_address_for_bridge(bridge, node);
add_an_entry_guard(node, 1, 1);
log_notice(LD_DIR, "new bridge descriptor '%s' (%s)", ri->nickname,
from_cache ? "cached" : "fresh");
/* set entry->made_contact so if it goes down we don't drop it from
* our entry node list */
entry_guard_register_connect_status(ri->cache_info.identity_digest,
1, 0, now);
if (first)
routerlist_retry_directory_downloads(now);
}
}
}
/** Return 1 if any of our entry guards have descriptors that
* are marked with purpose 'bridge' and are running. Else return 0.
*
* We use this function to decide if we're ready to start building
* circuits through our bridges, or if we need to wait until the
* directory "server/authority" requests finish. */
int
any_bridge_descriptors_known(void)
{
tor_assert(get_options()->UseBridges);
return choose_random_entry(NULL)!=NULL ? 1 : 0;
}
/** Return 1 if there are any directory conns fetching bridge descriptors
* that aren't marked for close. We use this to guess if we should tell
* the controller that we have a problem. */
int
any_pending_bridge_descriptor_fetches(void)
{
smartlist_t *conns = get_connection_array();
SMARTLIST_FOREACH(conns, connection_t *, conn,
{
if (conn->type == CONN_TYPE_DIR &&
conn->purpose == DIR_PURPOSE_FETCH_SERVERDESC &&
TO_DIR_CONN(conn)->router_purpose == ROUTER_PURPOSE_BRIDGE &&
!conn->marked_for_close &&
conn->linked &&
conn->linked_conn && !conn->linked_conn->marked_for_close) {
log_debug(LD_DIR, "found one: %s", conn->address);
return 1;
}
});
return 0;
}
/** Return 1 if we have at least one descriptor for an entry guard
* (bridge or member of EntryNodes) and all descriptors we know are
* down. Else return 0. If <b>act</b> is 1, then mark the down guards
* up; else just observe and report. */
static int
entries_retry_helper(const or_options_t *options, int act)
{
const node_t *node;
int any_known = 0;
int any_running = 0;
int need_bridges = options->UseBridges != 0;
if (!entry_guards)
entry_guards = smartlist_create();
SMARTLIST_FOREACH_BEGIN(entry_guards, entry_guard_t *, e) {
node = node_get_by_id(e->identity);
if (node && node_has_descriptor(node) &&
node_is_bridge(node) == need_bridges) {
any_known = 1;
if (node->is_running)
any_running = 1; /* some entry is both known and running */
else if (act) {
/* Mark all current connections to this OR as unhealthy, since
* otherwise there could be one that started 30 seconds
* ago, and in 30 seconds it will time out, causing us to mark
* the node down and undermine the retry attempt. We mark even
* the established conns, since if the network just came back
* we'll want to attach circuits to fresh conns. */
connection_or_set_bad_connections(node->identity, 1);
/* mark this entry node for retry */
router_set_status(node->identity, 1);
e->can_retry = 1;
e->bad_since = 0;
}
}
} SMARTLIST_FOREACH_END(e);
log_debug(LD_DIR, "%d: any_known %d, any_running %d",
act, any_known, any_running);
return any_known && !any_running;
}
/** Do we know any descriptors for our bridges / entrynodes, and are
* all the ones we have descriptors for down? */
int
entries_known_but_down(const or_options_t *options)
{
tor_assert(entry_list_is_constrained(options));
return entries_retry_helper(options, 0);
}
/** Mark all down known bridges / entrynodes up. */
void
entries_retry_all(const or_options_t *options)
{
tor_assert(entry_list_is_constrained(options));
entries_retry_helper(options, 1);
}
/** Release all storage held by the list of entry guards and related
* memory structs. */
void
entry_guards_free_all(void)
{
if (entry_guards) {
SMARTLIST_FOREACH(entry_guards, entry_guard_t *, e,
entry_guard_free(e));
smartlist_free(entry_guards);
entry_guards = NULL;
}
clear_bridge_list();
clear_transport_list();
smartlist_free(bridge_list);
smartlist_free(transport_list);
bridge_list = NULL;
transport_list = NULL;
}
Reference in New Issue View Git Blame Copy Permalink