/* Copyright (c) 2003-2004, Roger Dingledine.
* Copyright (c) 2004-2006, Roger Dingledine, Nick Mathewson.
* Copyright (c) 2007-2013, The Tor Project, Inc. */
/* See LICENSE for licensing information */
/**
* \file cpuworker.c
* \brief Implements a farm of 'CPU worker' processes to perform
* CPU-intensive tasks in another thread or process, to not
* interrupt the main thread.
*
* Right now, we only use this for processing onionskins.
**/
#include "or.h"
#include "buffers.h"
#include "channel.h"
#include "channeltls.h"
#include "circuitbuild.h"
#include "circuitlist.h"
#include "config.h"
#include "connection.h"
#include "cpuworker.h"
#include "main.h"
#include "onion.h"
#include "router.h"
/** The maximum number of cpuworker processes we will keep around. */
#define MAX_CPUWORKERS 16
/** The minimum number of cpuworker processes we will keep around. */
#define MIN_CPUWORKERS 1
/** The tag specifies which circuit this onionskin was from. */
#define TAG_LEN 12
/** How many cpuworkers we have running right now. */
static int num_cpuworkers=0;
/** How many of the running cpuworkers have an assigned task right now. */
static int num_cpuworkers_busy=0;
/** We need to spawn new cpuworkers whenever we rotate the onion keys
* on platforms where execution contexts==processes. This variable stores
* the last time we got a key rotation event. */
static time_t last_rotation_time=0;
static void cpuworker_main(void *data) ATTR_NORETURN;
static int spawn_cpuworker(void);
static void spawn_enough_cpuworkers(void);
static void process_pending_task(connection_t *cpuworker);
/** Initialize the cpuworker subsystem.
*/
void
cpu_init(void)
{
cpuworkers_rotate();
}
/** Called when we're done sending a request to a cpuworker. */
int
connection_cpu_finished_flushing(connection_t *conn)
{
tor_assert(conn);
tor_assert(conn->type == CONN_TYPE_CPUWORKER);
return 0;
}
/** Pack global_id and circ_id; set *tag to the result. (See note on
* cpuworker_main for wire format.) */
static void
tag_pack(uint8_t *tag, uint64_t chan_id, circid_t circ_id)
{
/*XXXX RETHINK THIS WHOLE MESS !!!! !NM NM NM NM*/
/*XXXX DOUBLEPLUSTHIS!!!! AS AS AS AS*/
set_uint64(tag, chan_id);
set_uint32(tag+8, circ_id);
}
/** Unpack tag into addr, port, and circ_id.
*/
static void
tag_unpack(const uint8_t *tag, uint64_t *chan_id, circid_t *circ_id)
{
*chan_id = get_uint64(tag);
*circ_id = get_uint32(tag+8);
}
/** Magic numbers to make sure our cpuworker_requests don't grow any
* mis-framing bugs. */
#define CPUWORKER_REQUEST_MAGIC 0xda4afeed
#define CPUWORKER_REPLY_MAGIC 0x5eedf00d
/** A request sent to a cpuworker. */
typedef struct cpuworker_request_t {
/** Magic number; must be CPUWORKER_REQUEST_MAGIC. */
uint32_t magic;
/** Opaque tag to identify the job */
uint8_t tag[TAG_LEN];
/** Task code. Must be one of CPUWORKER_TASK_* */
uint8_t task;
/** Flag: Are we timing this request? */
unsigned timed : 1;
/** If we're timing this request, when was it sent to the cpuworker? */
struct timeval started_at;
/** A create cell for the cpuworker to process. */
create_cell_t create_cell;
/* Turn the above into a tagged union if needed. */
} cpuworker_request_t;
/** A reply sent by a cpuworker. */
typedef struct cpuworker_reply_t {
/** Magic number; must be CPUWORKER_REPLY_MAGIC. */
uint32_t magic;
/** Opaque tag to identify the job; matches the request's tag.*/
uint8_t tag[TAG_LEN];
/** True iff we got a successful request. */
uint8_t success;
/** Are we timing this request? */
unsigned int timed : 1;
/** What handshake type was the request? (Used for timing) */
uint16_t handshake_type;
/** When did we send the request to the cpuworker? */
struct timeval started_at;
/** Once the cpuworker received the request, how many microseconds did it
* take? (This shouldn't overflow; 4 billion micoseconds is over an hour,
* and we'll never have an onion handshake that takes so long.) */
uint32_t n_usec;
/** Output of processing a create cell
*
* @{
*/
/** The created cell to send back. */
created_cell_t created_cell;
/** The keys to use on this circuit. */
uint8_t keys[CPATH_KEY_MATERIAL_LEN];
/** Input to use for authenticating introduce1 cells. */
uint8_t rend_auth_material[DIGEST_LEN];
} cpuworker_reply_t;
/** Called when the onion key has changed and we need to spawn new
* cpuworkers. Close all currently idle cpuworkers, and mark the last
* rotation time as now.
*/
void
cpuworkers_rotate(void)
{
connection_t *cpuworker;
while ((cpuworker = connection_get_by_type_state(CONN_TYPE_CPUWORKER,
CPUWORKER_STATE_IDLE))) {
connection_mark_for_close(cpuworker);
--num_cpuworkers;
}
last_rotation_time = time(NULL);
if (server_mode(get_options()))
spawn_enough_cpuworkers();
}
/** If the cpuworker closes the connection,
* mark it as closed and spawn a new one as needed. */
int
connection_cpu_reached_eof(connection_t *conn)
{
log_warn(LD_GENERAL,"Read eof. CPU worker died unexpectedly.");
if (conn->state != CPUWORKER_STATE_IDLE) {
/* the circ associated with this cpuworker will have to wait until
* it gets culled in run_connection_housekeeping(), since we have
* no way to find out which circ it was. */
log_warn(LD_GENERAL,"...and it left a circuit queued; abandoning circ.");
num_cpuworkers_busy--;
}
num_cpuworkers--;
spawn_enough_cpuworkers(); /* try to regrow. hope we don't end up
spinning. */
connection_mark_for_close(conn);
return 0;
}
/** Indexed by handshake type: how many onionskins have we processed and
* counted of that type? */
static uint64_t onionskins_n_processed[MAX_ONION_HANDSHAKE_TYPE+1];
/** Indexed by handshake type, corresponding to the onionskins counted in
* onionskins_n_processed: how many microseconds have we spent in cpuworkers
* processing that kind of onionskin? */
static uint64_t onionskins_usec_internal[MAX_ONION_HANDSHAKE_TYPE+1];
/** Indexed by handshake type, corresponding to onionskins counted in
* onionskins_n_processed: how many microseconds have we spent waiting for
* cpuworkers to give us answers for that kind of onionskin?
*/
static uint64_t onionskins_usec_roundtrip[MAX_ONION_HANDSHAKE_TYPE+1];
/** If any onionskin takes longer than this, we clip them to this
* time. (microseconds) */
#define MAX_BELIEVABLE_ONIONSKIN_DELAY (2*1000*1000)
static tor_weak_rng_t request_sample_rng = TOR_WEAK_RNG_INIT;
/** Return true iff we'd like to measure a handshake of type
* onionskin_type. Call only from the main thread. */
static int
should_time_request(uint16_t onionskin_type)
{
/* If we've never heard of this type, we shouldn't even be here. */
if (onionskin_type > MAX_ONION_HANDSHAKE_TYPE)
return 0;
/* Measure the first N handshakes of each type, to ensure we have a
* sample */
if (onionskins_n_processed[onionskin_type] < 4096)
return 1;
/** Otherwise, measure with P=1/128. We avoid doing this for every
* handshake, since the measurement itself can take a little time. */
return tor_weak_random_one_in_n(&request_sample_rng, 128);
}
/** Return an estimate of how many microseconds we will need for a single
* cpuworker to to process n_requests onionskins of type
* onionskin_type. */
uint64_t
estimated_usec_for_onionskins(uint32_t n_requests, uint16_t onionskin_type)
{
if (onionskin_type > MAX_ONION_HANDSHAKE_TYPE) /* should be impossible */
return 1000 * (uint64_t)n_requests;
if (PREDICT_UNLIKELY(onionskins_n_processed[onionskin_type] < 100)) {
/* Until we have 100 data points, just asssume everything takes 1 msec. */
return 1000 * (uint64_t)n_requests;
} else {
/* This can't overflow: we'll never have more than 500000 onionskins
* measured in onionskin_usec_internal, and they won't take anything near
* 1 sec each, and we won't have anything like 1 million queued
* onionskins. But that's 5e5 * 1e6 * 1e6, which is still less than
* UINT64_MAX. */
return (onionskins_usec_internal[onionskin_type] * n_requests) /
onionskins_n_processed[onionskin_type];
}
}
/** Compute the absolute and relative overhead of using the cpuworker
* framework for onionskins of type onionskin_type.*/
static int
get_overhead_for_onionskins(uint32_t *usec_out, double *frac_out,
uint16_t onionskin_type)
{
uint64_t overhead;
*usec_out = 0;
*frac_out = 0.0;
if (onionskin_type > MAX_ONION_HANDSHAKE_TYPE) /* should be impossible */
return -1;
if (onionskins_n_processed[onionskin_type] == 0 ||
onionskins_usec_internal[onionskin_type] == 0 ||
onionskins_usec_roundtrip[onionskin_type] == 0)
return -1;
overhead = onionskins_usec_roundtrip[onionskin_type] -
onionskins_usec_internal[onionskin_type];
*usec_out = (uint32_t)(overhead / onionskins_n_processed[onionskin_type]);
*frac_out = U64_TO_DBL(overhead) / onionskins_usec_internal[onionskin_type];
return 0;
}
/** If we've measured overhead for onionskins of type onionskin_type,
* log it. */
void
cpuworker_log_onionskin_overhead(int severity, int onionskin_type,
const char *onionskin_type_name)
{
uint32_t overhead;
double relative_overhead;
int r;
r = get_overhead_for_onionskins(&overhead, &relative_overhead,
onionskin_type);
if (!overhead || r<0)
return;
log_fn(severity, LD_OR,
"%s onionskins have averaged %u usec overhead (%.2f%%) in "
"cpuworker code ",
onionskin_type_name, (unsigned)overhead, relative_overhead*100);
}
/** Called when we get data from a cpuworker. If the answer is not complete,
* wait for a complete answer. If the answer is complete,
* process it as appropriate.
*/
int
connection_cpu_process_inbuf(connection_t *conn)
{
uint64_t chan_id;
circid_t circ_id;
channel_t *p_chan = NULL;
circuit_t *circ;
tor_assert(conn);
tor_assert(conn->type == CONN_TYPE_CPUWORKER);
if (!connection_get_inbuf_len(conn))
return 0;
if (conn->state == CPUWORKER_STATE_BUSY_ONION) {
cpuworker_reply_t rpl;
if (connection_get_inbuf_len(conn) < sizeof(cpuworker_reply_t))
return 0; /* not yet */
tor_assert(connection_get_inbuf_len(conn) == sizeof(cpuworker_reply_t));
connection_fetch_from_buf((void*)&rpl,sizeof(cpuworker_reply_t),conn);
tor_assert(rpl.magic == CPUWORKER_REPLY_MAGIC);
if (rpl.timed && rpl.success &&
rpl.handshake_type <= MAX_ONION_HANDSHAKE_TYPE) {
/* Time how long this request took. The handshake_type check should be
needless, but let's leave it in to be safe. */
struct timeval tv_end, tv_diff;
int64_t usec_roundtrip;
tor_gettimeofday(&tv_end);
timersub(&tv_end, &rpl.started_at, &tv_diff);
usec_roundtrip = ((int64_t)tv_diff.tv_sec)*1000000 + tv_diff.tv_usec;
if (usec_roundtrip >= 0 &&
usec_roundtrip < MAX_BELIEVABLE_ONIONSKIN_DELAY) {
++onionskins_n_processed[rpl.handshake_type];
onionskins_usec_internal[rpl.handshake_type] += rpl.n_usec;
onionskins_usec_roundtrip[rpl.handshake_type] += usec_roundtrip;
if (onionskins_n_processed[rpl.handshake_type] >= 500000) {
/* Scale down every 500000 handshakes. On a busy server, that's
* less impressive than it sounds. */
onionskins_n_processed[rpl.handshake_type] /= 2;
onionskins_usec_internal[rpl.handshake_type] /= 2;
onionskins_usec_roundtrip[rpl.handshake_type] /= 2;
}
}
}
/* parse out the circ it was talking about */
tag_unpack(rpl.tag, &chan_id, &circ_id);
circ = NULL;
log_debug(LD_OR,
"Unpacking cpuworker reply, chan_id is " U64_FORMAT
", circ_id is %d",
U64_PRINTF_ARG(chan_id), circ_id);
p_chan = channel_find_by_global_id(chan_id);
if (p_chan)
circ = circuit_get_by_circid_channel(circ_id, p_chan);
if (rpl.success == 0) {
log_debug(LD_OR,
"decoding onionskin failed. "
"(Old key or bad software.) Closing.");
if (circ)
circuit_mark_for_close(circ, END_CIRC_REASON_TORPROTOCOL);
goto done_processing;
}
if (!circ) {
/* This happens because somebody sends us a destroy cell and the
* circuit goes away, while the cpuworker is working. This is also
* why our tag doesn't include a pointer to the circ, because we'd
* never know if it's still valid.
*/
log_debug(LD_OR,"processed onion for a circ that's gone. Dropping.");
goto done_processing;
}
tor_assert(! CIRCUIT_IS_ORIGIN(circ));
if (onionskin_answer(TO_OR_CIRCUIT(circ),
&rpl.created_cell,
(const char*)rpl.keys,
rpl.rend_auth_material) < 0) {
log_warn(LD_OR,"onionskin_answer failed. Closing.");
circuit_mark_for_close(circ, END_CIRC_REASON_INTERNAL);
goto done_processing;
}
log_debug(LD_OR,"onionskin_answer succeeded. Yay.");
} else {
tor_assert(0); /* don't ask me to do handshakes yet */
}
done_processing:
conn->state = CPUWORKER_STATE_IDLE;
num_cpuworkers_busy--;
if (conn->timestamp_created < last_rotation_time) {
connection_mark_for_close(conn);
num_cpuworkers--;
spawn_enough_cpuworkers();
} else {
process_pending_task(conn);
}
return 0;
}
/** Implement a cpuworker. 'data' is an fdarray as returned by socketpair.
* Read and writes from fdarray[1]. Reads requests, writes answers.
*
* Request format:
* cpuworker_request_t.
* Response format:
* cpuworker_reply_t
*/
static void
cpuworker_main(void *data)
{
/* For talking to the parent thread/process */
tor_socket_t *fdarray = data;
tor_socket_t fd;
/* variables for onion processing */
server_onion_keys_t onion_keys;
cpuworker_request_t req;
cpuworker_reply_t rpl;
fd = fdarray[1]; /* this side is ours */
#ifndef TOR_IS_MULTITHREADED
tor_close_socket(fdarray[0]); /* this is the side of the socketpair the
* parent uses */
tor_free_all(1); /* so the child doesn't hold the parent's fd's open */
handle_signals(0); /* ignore interrupts from the keyboard, etc */
#endif
tor_free(data);
setup_server_onion_keys(&onion_keys);
for (;;) {
if (read_all(fd, (void *)&req, sizeof(req), 1) != sizeof(req)) {
log_info(LD_OR, "read request failed. Exiting.");
goto end;
}
tor_assert(req.magic == CPUWORKER_REQUEST_MAGIC);
memset(&rpl, 0, sizeof(rpl));
if (req.task == CPUWORKER_TASK_ONION) {
const create_cell_t *cc = &req.create_cell;
created_cell_t *cell_out = &rpl.created_cell;
struct timeval tv_start, tv_end;
int n;
rpl.timed = req.timed;
rpl.started_at = req.started_at;
rpl.handshake_type = cc->handshake_type;
if (req.timed)
tor_gettimeofday(&tv_start);
n = onion_skin_server_handshake(cc->handshake_type,
cc->onionskin, cc->handshake_len,
&onion_keys,
cell_out->reply,
rpl.keys, CPATH_KEY_MATERIAL_LEN,
rpl.rend_auth_material);
if (n < 0) {
/* failure */
log_debug(LD_OR,"onion_skin_server_handshake failed.");
memset(&rpl, 0, sizeof(rpl));
memcpy(rpl.tag, req.tag, TAG_LEN);
rpl.success = 0;
} else {
/* success */
log_debug(LD_OR,"onion_skin_server_handshake succeeded.");
memcpy(rpl.tag, req.tag, TAG_LEN);
cell_out->handshake_len = n;
switch (cc->cell_type) {
case CELL_CREATE:
cell_out->cell_type = CELL_CREATED; break;
case CELL_CREATE2:
cell_out->cell_type = CELL_CREATED2; break;
case CELL_CREATE_FAST:
cell_out->cell_type = CELL_CREATED_FAST; break;
default:
tor_assert(0);
goto end;
}
rpl.success = 1;
}
rpl.magic = CPUWORKER_REPLY_MAGIC;
if (req.timed) {
struct timeval tv_diff;
int64_t usec;
tor_gettimeofday(&tv_end);
timersub(&tv_end, &tv_start, &tv_diff);
usec = ((int64_t)tv_diff.tv_sec)*1000000 + tv_diff.tv_usec;
if (usec < 0 || usec > MAX_BELIEVABLE_ONIONSKIN_DELAY)
rpl.n_usec = MAX_BELIEVABLE_ONIONSKIN_DELAY;
else
rpl.n_usec = (uint32_t) usec;
}
if (write_all(fd, (void*)&rpl, sizeof(rpl), 1) != sizeof(rpl)) {
log_err(LD_BUG,"writing response buf failed. Exiting.");
goto end;
}
log_debug(LD_OR,"finished writing response.");
} else if (req.task == CPUWORKER_TASK_SHUTDOWN) {
log_info(LD_OR,"Clean shutdown: exiting");
goto end;
}
memwipe(&req, 0, sizeof(req));
memwipe(&rpl, 0, sizeof(req));
}
end:
memwipe(&req, 0, sizeof(req));
memwipe(&rpl, 0, sizeof(req));
release_server_onion_keys(&onion_keys);
tor_close_socket(fd);
crypto_thread_cleanup();
spawn_exit();
}
/** Launch a new cpuworker. Return 0 if we're happy, -1 if we failed.
*/
static int
spawn_cpuworker(void)
{
tor_socket_t *fdarray;
tor_socket_t fd;
connection_t *conn;
int err;
fdarray = tor_malloc(sizeof(tor_socket_t)*2);
if ((err = tor_socketpair(AF_UNIX, SOCK_STREAM, 0, fdarray)) < 0) {
log_warn(LD_NET, "Couldn't construct socketpair for cpuworker: %s",
tor_socket_strerror(-err));
tor_free(fdarray);
return -1;
}
tor_assert(SOCKET_OK(fdarray[0]));
tor_assert(SOCKET_OK(fdarray[1]));
fd = fdarray[0];
spawn_func(cpuworker_main, (void*)fdarray);
log_debug(LD_OR,"just spawned a cpu worker.");
#ifndef TOR_IS_MULTITHREADED
tor_close_socket(fdarray[1]); /* don't need the worker's side of the pipe */
tor_free(fdarray);
#endif
conn = connection_new(CONN_TYPE_CPUWORKER, AF_UNIX);
set_socket_nonblocking(fd);
/* set up conn so it's got all the data we need to remember */
conn->s = fd;
conn->address = tor_strdup("localhost");
tor_addr_make_unspec(&conn->addr);
if (connection_add(conn) < 0) { /* no space, forget it */
log_warn(LD_NET,"connection_add for cpuworker failed. Giving up.");
connection_free(conn); /* this closes fd */
return -1;
}
conn->state = CPUWORKER_STATE_IDLE;
connection_start_reading(conn);
return 0; /* success */
}
/** If we have too few or too many active cpuworkers, try to spawn new ones
* or kill idle ones.
*/
static void
spawn_enough_cpuworkers(void)
{
int num_cpuworkers_needed = get_num_cpus(get_options());
int reseed = 0;
if (num_cpuworkers_needed < MIN_CPUWORKERS)
num_cpuworkers_needed = MIN_CPUWORKERS;
if (num_cpuworkers_needed > MAX_CPUWORKERS)
num_cpuworkers_needed = MAX_CPUWORKERS;
while (num_cpuworkers < num_cpuworkers_needed) {
if (spawn_cpuworker() < 0) {
log_warn(LD_GENERAL,"Cpuworker spawn failed. Will try again later.");
return;
}
num_cpuworkers++;
reseed++;
}
if (reseed)
crypto_seed_weak_rng(&request_sample_rng);
}
/** Take a pending task from the queue and assign it to 'cpuworker'. */
static void
process_pending_task(connection_t *cpuworker)
{
or_circuit_t *circ;
create_cell_t *onionskin = NULL;
tor_assert(cpuworker);
/* for now only process onion tasks */
circ = onion_next_task(&onionskin);
if (!circ)
return;
if (assign_onionskin_to_cpuworker(cpuworker, circ, onionskin))
log_warn(LD_OR,"assign_to_cpuworker failed. Ignoring.");
}
/** How long should we let a cpuworker stay busy before we give
* up on it and decide that we have a bug or infinite loop?
* This value is high because some servers with low memory/cpu
* sometimes spend an hour or more swapping, and Tor starves. */
#define CPUWORKER_BUSY_TIMEOUT (60*60*12)
/** We have a bug that I can't find. Sometimes, very rarely, cpuworkers get
* stuck in the 'busy' state, even though the cpuworker process thinks of
* itself as idle. I don't know why. But here's a workaround to kill any
* cpuworker that's been busy for more than CPUWORKER_BUSY_TIMEOUT.
*/
static void
cull_wedged_cpuworkers(void)
{
time_t now = time(NULL);
smartlist_t *conns = get_connection_array();
SMARTLIST_FOREACH_BEGIN(conns, connection_t *, conn) {
if (!conn->marked_for_close &&
conn->type == CONN_TYPE_CPUWORKER &&
conn->state == CPUWORKER_STATE_BUSY_ONION &&
conn->timestamp_lastwritten + CPUWORKER_BUSY_TIMEOUT < now) {
log_notice(LD_BUG,
"closing wedged cpuworker. Can somebody find the bug?");
num_cpuworkers_busy--;
num_cpuworkers--;
connection_mark_for_close(conn);
}
} SMARTLIST_FOREACH_END(conn);
}
/** Try to tell a cpuworker to perform the public key operations necessary to
* respond to onionskin for the circuit circ.
*
* If cpuworker is defined, assert that he's idle, and use him. Else,
* look for an idle cpuworker and use him. If none idle, queue task onto the
* pending onion list and return. Return 0 if we successfully assign the
* task, or -1 on failure.
*/
int
assign_onionskin_to_cpuworker(connection_t *cpuworker,
or_circuit_t *circ,
create_cell_t *onionskin)
{
cpuworker_request_t req;
time_t now = approx_time();
static time_t last_culled_cpuworkers = 0;
int should_time;
/* Checking for wedged cpuworkers requires a linear search over all
* connections, so let's do it only once a minute.
*/
#define CULL_CPUWORKERS_INTERVAL 60
if (last_culled_cpuworkers + CULL_CPUWORKERS_INTERVAL <= now) {
cull_wedged_cpuworkers();
spawn_enough_cpuworkers();
last_culled_cpuworkers = now;
}
if (1) {
if (num_cpuworkers_busy == num_cpuworkers) {
log_debug(LD_OR,"No idle cpuworkers. Queuing.");
if (onion_pending_add(circ, onionskin) < 0) {
tor_free(onionskin);
return -1;
}
return 0;
}
if (!cpuworker)
cpuworker = connection_get_by_type_state(CONN_TYPE_CPUWORKER,
CPUWORKER_STATE_IDLE);
tor_assert(cpuworker);
if (!circ->p_chan) {
log_info(LD_OR,"circ->p_chan gone. Failing circ.");
tor_free(onionskin);
return -1;
}
should_time = should_time_request(onionskin->handshake_type);
memset(&req, 0, sizeof(req));
req.magic = CPUWORKER_REQUEST_MAGIC;
tag_pack(req.tag, circ->p_chan->global_identifier,
circ->p_circ_id);
req.timed = should_time;
cpuworker->state = CPUWORKER_STATE_BUSY_ONION;
/* touch the lastwritten timestamp, since that's how we check to
* see how long it's been since we asked the question, and sometimes
* we check before the first call to connection_handle_write(). */
cpuworker->timestamp_lastwritten = now;
num_cpuworkers_busy++;
req.task = CPUWORKER_TASK_ONION;
memcpy(&req.create_cell, onionskin, sizeof(create_cell_t));
tor_free(onionskin);
if (should_time)
tor_gettimeofday(&req.started_at);
connection_write_to_buf((void*)&req, sizeof(req), cpuworker);
memwipe(&req, 0, sizeof(req));
}
return 0;
}