/**
* mds — A micro-display server
* Copyright © 2014, 2015 Mattias Andrée (maandree@member.fsf.org)
*
* This program is free software: you can redistribute it and/or modify
* it under the terms of the GNU General Public License as published by
* the Free Software Foundation, either version 3 of the License, or
* (at your option) any later version.
*
* This program is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with this program. If not, see .
*/
#include "slave.h"
#include "util.h"
#include "globals.h"
#include "../mds-base.h"
#include
#include
#include
#include
#include
#include
/**
* Notify the waiting client that it may resume
*
* @param slave The slave
* @return Non-zero, `errno` will be set accordingly
*/
__attribute__((nonnull))
static int slave_notify_client(slave_t* slave)
{
char buf[sizeof("To: %s\nIn response to: %s\nMessage ID: %" PRIu32 "\nOrigin command: register\n\n")
/ sizeof(char) + 41];
size_t ptr = 0, sent, left;
/* Construct message headers. */
sprintf(buf, "To: %s\nIn response to: %s\nMessage ID: %" PRIu32 "\nOrigin command: register\n\n",
slave->client_id, slave->message_id, message_id);
/* Increase message ID. */
message_id = message_id == UINT32_MAX ? 0 : (message_id + 1);
/* Send message to client. */
left = strlen(buf);
while (left > 0)
{
sent = send_message(socket_fd, buf + ptr, left);
fail_if ((sent < left) && errno && (errno != EINTR));
left -= sent;
ptr += sent;
}
return 0;
fail:
return -1;
}
/**
* Master function for slave threads
*
* @param data Input data
* @return Output data
*/
static void* slave_loop(void* data)
{
/* pthread_cond_timedwait is required to handle re-exec and termination because
pthread_cond_timedwait and pthread_cond_wait ignore interruptions via signals. */
struct timespec timeout =
{
.tv_sec = 1,
.tv_nsec = 0
};
slave_t* slave = data;
struct timespec now;
if (slave->closed)
goto done;
/* Set up traps for especially handled signals. */
fail_if (trap_signals() < 0);
fail_if ((errno = pthread_mutex_lock(&slave_mutex)));
while (!reexecing && !terminating)
{
if ((slave->wait_set->size == 0) || slave->closed)
break;
if (slave->timed)
{
fail_if (monotone(&now));
if (now.tv_sec > slave->dethklok.tv_sec)
break;
if (now.tv_sec == slave->dethklok.tv_sec)
if (now.tv_nsec >= slave->dethklok.tv_nsec)
break;
}
pthread_cond_timedwait(&slave_cond, &slave_mutex, &timeout);
}
if (!(slave->closed) && (slave->wait_set->size == 0))
slave_notify_client(slave);
pthread_mutex_unlock(&slave_mutex);
goto done;
fail:
xperror(*argv);
done:
with_mutex (slave_mutex,
if (!reexecing)
linked_list_remove(&slave_list, slave->node);
running_slaves--;
if (running_slaves == 0)
pthread_cond_signal(&slave_cond);
);
return NULL;
}
/**
* Start a slave thread with an already created slave
*
* @param slave The slave
* @return Non-zero on error, `errno` will be set accordingly
*/
int start_created_slave(slave_t* restrict slave)
{
int locked = 0;
fail_if ((errno = pthread_mutex_lock(&slave_mutex)));
locked = 1;
fail_if ((errno = pthread_create(&(slave->thread), NULL, slave_loop, (void*)(intptr_t)slave)));
if ((errno = pthread_detach(slave->thread)))
xperror(*argv);
running_slaves++;
pthread_mutex_unlock(&slave_mutex);
return 0;
fail:
if (locked)
pthread_mutex_unlock(&slave_mutex);
return -1;
}
/**
* Start a slave thread
*
* @param wait_set Set of protocols for which to wait that they become available
* @param recv_client_id The ID of the waiting client
* @param recv_message_id The ID of the message that triggered the waiting
* @return Non-zero on error
*/
int start_slave(hash_table_t* restrict wait_set, const char* restrict recv_client_id,
const char* restrict recv_message_id)
{
slave_t* slave = slave_create(wait_set, recv_client_id, recv_message_id);
size_t slave_address, i;
ssize_t node = LINKED_LIST_UNUSED;
int locked = 0;
fail_if (slave == NULL);
fail_if ((errno = pthread_mutex_lock(&slave_mutex)));
locked = 1;
slave_address = (size_t)(void*)slave;
slave->node = node = linked_list_insert_end(&slave_list, slave_address);
fail_if (slave->node == LINKED_LIST_UNUSED);
for (i = 0; i < received.header_count; i++)
if (startswith(received.headers[i], "Time to live: "))
{
const char* ttl = received.headers[i] + strlen("Time to live: ");
slave->timed = 1;
fail_if (monotone(&(slave->dethklok)));
slave->dethklok.tv_sec += (time_t)atoll(ttl);
/* It should really be `atol`, but we want to be future-proof. */
break;
}
fail_if ((errno = pthread_create(&(slave->thread), NULL, slave_loop, (void*)(intptr_t)slave)));
if ((errno = pthread_detach(slave->thread)))
xperror(*argv);
running_slaves++;
pthread_mutex_unlock(&slave_mutex);
return 0;
fail:
xperror(*argv);
if (locked)
pthread_mutex_unlock(&slave_mutex);
if (node != LINKED_LIST_UNUSED)
linked_list_remove(&slave_list, node);
return -1;
}
/**
* Close all slaves associated with a client
*
* @param client The client's ID
*/
void close_slaves(uint64_t client)
{
ssize_t node;
with_mutex (slave_mutex,
foreach_linked_list_node (slave_list, node)
{
slave_t* slave = (slave_t*)(void*)(slave_list.values[node]);
if (slave->client == client)
slave->closed = 1;
}
);
}
/**
* Notify slaves that a protocol has become available
*
* @param command The protocol
* @return Non-zero on error, `ernno`will be set accordingly
*/
int advance_slaves(char* command)
{
size_t key = (size_t)(void*)command;
int signal_slaves = 0;
ssize_t node;
fail_if ((errno = pthread_mutex_lock(&slave_mutex)));
foreach_linked_list_node (slave_list, node)
{
slave_t* slave = (slave_t*)(void*)(slave_list.values[node]);
if (hash_table_contains_key(slave->wait_set, key))
{
hash_table_remove(slave->wait_set, key);
signal_slaves |= slave->wait_set == 0;
}
}
if (signal_slaves)
pthread_cond_broadcast(&slave_cond);
pthread_mutex_unlock(&slave_mutex);
return 0;
fail:
return -1;
}
/**
* Create a slave
*
* @param wait_set Set of protocols for which to wait that they become available
* @param recv_client_id The ID of the waiting client
* @param recv_message_id The ID of the message that triggered the waiting
* @return The slave, `NULL` on error, `errno` will be set accordingly
*/
slave_t* slave_create(hash_table_t* restrict wait_set, const char* restrict recv_client_id,
const char* restrict recv_message_id)
{
slave_t* restrict rc = NULL;
int saved_errno;
fail_if (xmalloc(rc, 1, slave_t));
slave_initialise(rc);
rc->wait_set = wait_set;
rc->client = parse_client_id(recv_client_id);
fail_if (xstrdup(rc->client_id, recv_client_id));
fail_if (xstrdup(rc->message_id, recv_message_id));
return rc;
fail:
saved_errno = errno;
slave_destroy(rc), free(rc);
return errno = saved_errno, NULL;
}
/**
* Initialise a slave
*
* @param this Memory slot in which to store the new slave information
*/
void slave_initialise(slave_t* restrict this)
{
this->wait_set = NULL;
this->client_id = NULL;
this->message_id = NULL;
this->closed = 0;
this->dethklok.tv_sec = 0;
this->dethklok.tv_nsec = 0;
this->timed = 0;
}
/**
* Release all resources assoicated with a slave
*
* @param this The slave information
*/
void slave_destroy(slave_t* restrict this)
{
if (this == NULL)
return;
if (this->wait_set != NULL)
{
hash_table_destroy(this->wait_set, (free_func*)reg_table_free_key, NULL);
free(this->wait_set);
this->wait_set = NULL;
}
free(this->client_id);
this->client_id = NULL;
free(this->message_id);
this->message_id = NULL;
}
/**
* Calculate the buffer size need to marshal slave information
*
* @param this The slave information
* @return The number of bytes to allocate to the output buffer
*/
size_t slave_marshal_size(const slave_t* restrict this)
{
size_t rc;
hash_entry_t* restrict entry;
size_t n;
rc = sizeof(int) + sizeof(sig_atomic_t) + sizeof(ssize_t) + sizeof(size_t) + sizeof(uint64_t);
rc += sizeof(int) + sizeof(time_t) + sizeof(long);
rc += (strlen(this->client_id) + strlen(this->message_id) + 2) * sizeof(char);
foreach_hash_table_entry (*(this->wait_set), n, entry)
{
char* protocol = (char*)(void*)(entry->key);
rc += strlen(protocol) + 1;
}
return rc;
}
/**
* Marshals slave information
*
* @param this The slave information
* @param data Output buffer for the marshalled data
* @return The number of bytes that have been written (everything will be written)
*/
size_t slave_marshal(const slave_t* restrict this, char* restrict data)
{
hash_entry_t* restrict entry;
size_t n;
buf_set_next(data, int, SLAVE_T_VERSION);
buf_set_next(data, sig_atomic_t, this->closed);
buf_set_next(data, ssize_t, this->node);
buf_set_next(data, uint64_t, this->client);
buf_set_next(data, int, this->timed);
buf_set_next(data, time_t, this->dethklok.tv_sec);
buf_set_next(data, long, this->dethklok.tv_nsec);
memcpy(data, this->client_id, (strlen(this->client_id) + 1) * sizeof(char));
data += strlen(this->client_id) + 1;
memcpy(data, this->message_id, (strlen(this->message_id) + 1) * sizeof(char));
data += strlen(this->message_id) + 1;
n = this->wait_set->size;
buf_set_next(data, size_t, n);
foreach_hash_table_entry (*(this->wait_set), n, entry)
{
char* restrict protocol = (char*)(void*)(entry->key);
memcpy(data, protocol, (strlen(protocol) + 1) * sizeof(char));
data += strlen(protocol) + 1;
}
return slave_marshal_size(this);
}
/**
* Unmarshals slave information
*
* @param this Memory slot in which to store the new slave information
* @param data In buffer with the marshalled data
* @return Zero on error, `errno` will be set accordingly, otherwise the
* number of read bytes. Destroy the slave information on error.
*/
size_t slave_unmarshal(slave_t* restrict this, char* restrict data)
{
size_t key, n, m, rc = 2 * sizeof(int) + sizeof(ssize_t) + sizeof(size_t) + sizeof(uint64_t);
char* protocol = NULL;
int saved_errno;
this->wait_set = NULL;
this->client_id = NULL;
this->message_id = NULL;
/* buf_get_next(data, int, SLAVE_T_VERSION); */
buf_next(data, int, 1);
buf_get_next(data, sig_atomic_t, this->closed);
buf_get_next(data, ssize_t, this->node);
buf_get_next(data, uint64_t, this->client);
buf_get_next(data, int, this->timed);
buf_get_next(data, time_t, this->dethklok.tv_sec);
buf_get_next(data, long, this->dethklok.tv_nsec);
n = strlen((char*)data) + 1;
fail_if (xmemdup(this->client_id, data, n, char));
data += n, rc += n * sizeof(char);
n = strlen((char*)data) + 1;
fail_if (xmemdup(this->message_id, data, n, char));
data += n, rc += n * sizeof(char);
fail_if (xmalloc(this->wait_set, 1, hash_table_t));
fail_if (hash_table_create(this->wait_set));
buf_get_next(data, size_t, m);
while (m--)
{
n = strlen((char*)data) + 1;
fail_if (xmemdup(protocol, data, n, char));
data += n, rc += n * sizeof(char);
key = (size_t)(void*)protocol;
if (hash_table_put(this->wait_set, key, 1) == 0)
fail_if (errno);
}
return rc;
fail:
saved_errno = errno;
free(protocol);
return errno = saved_errno, (size_t)0;
}
/**
* Pretend to unmarshal slave information
*
* @param data In buffer with the marshalled data
* @return The number of read bytes
*/
size_t slave_unmarshal_skip(char* restrict data)
{
size_t n, m, rc = 2 * sizeof(int) + sizeof(ssize_t) + sizeof(size_t) + sizeof(uint64_t);
rc += sizeof(int) + sizeof(time_t) + sizeof(long);
/* buf_get_next(data, int, SLAVE_T_VERSION); */
buf_next(data, int, 1);
buf_next(data, sig_atomic_t, 1);
buf_next(data, ssize_t, 1);
buf_next(data, uint64_t, 1);
buf_next(data, int, 1);
buf_next(data, time_t, 1);
buf_next(data, long, 1);
n = (strlen((char*)data) + 1) * sizeof(char);
data += n, rc += n;
n = (strlen((char*)data) + 1) * sizeof(char);
data += n, rc += n;
buf_get_next(data, size_t, m);
while (m--)
{
n = (strlen((char*)data) + 1) * sizeof(char);
data += n, rc += n;
}
return rc;
}