#include <stdio.h> #include <stdlib.h> #include <stdarg.h> #include <unistd.h> #include <limits.h> #include <errno.h> #include <sys/poll.h> #include <sys/types.h> #include <sys/wait.h> #include <sys/socket.h> #include <sys/stat.h> #include <sys/un.h> #include <sys/uio.h> #include <netinet/in.h> #include <arpa/inet.h> #include <netdb.h> #include <syslog.h> #include <signal.h> #ifdef CONFIG_ZLIB #include <zlib.h> #endif #include "fio.h" #include "options.h" #include "server.h" #include "crc/crc16.h" #include "lib/ieee754.h" #include "verify.h" #include "smalloc.h" int fio_net_port = FIO_NET_PORT; int exit_backend = 0; enum { SK_F_FREE = 1, SK_F_COPY = 2, SK_F_SIMPLE = 4, SK_F_VEC = 8, SK_F_INLINE = 16, }; struct sk_entry { struct flist_head list; /* link on sk_out->list */ int flags; /* SK_F_* */ int opcode; /* Actual command fields */ void *buf; off_t size; uint64_t tag; struct flist_head next; /* Other sk_entry's, if linked command */ }; static char *fio_server_arg; static char *bind_sock; static struct sockaddr_in saddr_in; static struct sockaddr_in6 saddr_in6; static int use_ipv6; #ifdef CONFIG_ZLIB static unsigned int has_zlib = 1; #else static unsigned int has_zlib = 0; #endif static unsigned int use_zlib; static char me[128]; static pthread_key_t sk_out_key; struct fio_fork_item { struct flist_head list; int exitval; int signal; int exited; pid_t pid; }; struct cmd_reply { struct fio_mutex lock; void *data; size_t size; int error; }; static const char *fio_server_ops[FIO_NET_CMD_NR] = { "", "QUIT", "EXIT", "JOB", "JOBLINE", "TEXT", "TS", "GS", "SEND_ETA", "ETA", "PROBE", "START", "STOP", "DISK_UTIL", "SERVER_START", "ADD_JOB", "RUN", "IOLOG", "UPDATE_JOB", "LOAD_FILE", "VTRIGGER", "SENDFILE", "JOB_OPT", }; static void sk_lock(struct sk_out *sk_out) { fio_mutex_down(&sk_out->lock); } static void sk_unlock(struct sk_out *sk_out) { fio_mutex_up(&sk_out->lock); } void sk_out_assign(struct sk_out *sk_out) { if (!sk_out) return; sk_lock(sk_out); sk_out->refs++; sk_unlock(sk_out); pthread_setspecific(sk_out_key, sk_out); } static void sk_out_free(struct sk_out *sk_out) { __fio_mutex_remove(&sk_out->lock); __fio_mutex_remove(&sk_out->wait); __fio_mutex_remove(&sk_out->xmit); sfree(sk_out); } static int __sk_out_drop(struct sk_out *sk_out) { if (sk_out) { int refs; sk_lock(sk_out); assert(sk_out->refs != 0); refs = --sk_out->refs; sk_unlock(sk_out); if (!refs) { sk_out_free(sk_out); pthread_setspecific(sk_out_key, NULL); return 0; } } return 1; } void sk_out_drop(void) { struct sk_out *sk_out; sk_out = pthread_getspecific(sk_out_key); __sk_out_drop(sk_out); } static void __fio_init_net_cmd(struct fio_net_cmd *cmd, uint16_t opcode, uint32_t pdu_len, uint64_t tag) { memset(cmd, 0, sizeof(*cmd)); cmd->version = __cpu_to_le16(FIO_SERVER_VER); cmd->opcode = cpu_to_le16(opcode); cmd->tag = cpu_to_le64(tag); cmd->pdu_len = cpu_to_le32(pdu_len); } static void fio_init_net_cmd(struct fio_net_cmd *cmd, uint16_t opcode, const void *pdu, uint32_t pdu_len, uint64_t tag) { __fio_init_net_cmd(cmd, opcode, pdu_len, tag); if (pdu) memcpy(&cmd->payload, pdu, pdu_len); } const char *fio_server_op(unsigned int op) { static char buf[32]; if (op < FIO_NET_CMD_NR) return fio_server_ops[op]; sprintf(buf, "UNKNOWN/%d", op); return buf; } static ssize_t iov_total_len(const struct iovec *iov, int count) { ssize_t ret = 0; while (count--) { ret += iov->iov_len; iov++; } return ret; } static int fio_sendv_data(int sk, struct iovec *iov, int count) { ssize_t total_len = iov_total_len(iov, count); ssize_t ret; do { ret = writev(sk, iov, count); if (ret > 0) { total_len -= ret; if (!total_len) break; while (ret) { if (ret >= iov->iov_len) { ret -= iov->iov_len; iov++; continue; } iov->iov_base += ret; iov->iov_len -= ret; ret = 0; } } else if (!ret) break; else if (errno == EAGAIN || errno == EINTR) continue; else break; } while (!exit_backend); if (!total_len) return 0; return 1; } static int fio_send_data(int sk, const void *p, unsigned int len) { struct iovec iov = { .iov_base = (void *) p, .iov_len = len }; assert(len <= sizeof(struct fio_net_cmd) + FIO_SERVER_MAX_FRAGMENT_PDU); return fio_sendv_data(sk, &iov, 1); } static int fio_recv_data(int sk, void *p, unsigned int len, bool wait) { int flags; if (wait) flags = MSG_WAITALL; else flags = OS_MSG_DONTWAIT; do { int ret = recv(sk, p, len, flags); if (ret > 0) { len -= ret; if (!len) break; p += ret; continue; } else if (!ret) break; else if (errno == EAGAIN || errno == EINTR) { if (wait) continue; break; } else break; } while (!exit_backend); if (!len) return 0; return -1; } static int verify_convert_cmd(struct fio_net_cmd *cmd) { uint16_t crc; cmd->cmd_crc16 = le16_to_cpu(cmd->cmd_crc16); cmd->pdu_crc16 = le16_to_cpu(cmd->pdu_crc16); crc = fio_crc16(cmd, FIO_NET_CMD_CRC_SZ); if (crc != cmd->cmd_crc16) { log_err("fio: server bad crc on command (got %x, wanted %x)\n", cmd->cmd_crc16, crc); return 1; } cmd->version = le16_to_cpu(cmd->version); cmd->opcode = le16_to_cpu(cmd->opcode); cmd->flags = le32_to_cpu(cmd->flags); cmd->tag = le64_to_cpu(cmd->tag); cmd->pdu_len = le32_to_cpu(cmd->pdu_len); switch (cmd->version) { case FIO_SERVER_VER: break; default: log_err("fio: bad server cmd version %d\n", cmd->version); return 1; } if (cmd->pdu_len > FIO_SERVER_MAX_FRAGMENT_PDU) { log_err("fio: command payload too large: %u\n", cmd->pdu_len); return 1; } return 0; } /* * Read (and defragment, if necessary) incoming commands */ struct fio_net_cmd *fio_net_recv_cmd(int sk, bool wait) { struct fio_net_cmd cmd, *tmp, *cmdret = NULL; size_t cmd_size = 0, pdu_offset = 0; uint16_t crc; int ret, first = 1; void *pdu = NULL; do { ret = fio_recv_data(sk, &cmd, sizeof(cmd), wait); if (ret) break; /* We have a command, verify it and swap if need be */ ret = verify_convert_cmd(&cmd); if (ret) break; if (first) { /* if this is text, add room for \0 at the end */ cmd_size = sizeof(cmd) + cmd.pdu_len + 1; assert(!cmdret); } else cmd_size += cmd.pdu_len; if (cmd_size / 1024 > FIO_SERVER_MAX_CMD_MB * 1024) { log_err("fio: cmd+pdu too large (%llu)\n", (unsigned long long) cmd_size); ret = 1; break; } tmp = realloc(cmdret, cmd_size); if (!tmp) { log_err("fio: server failed allocating cmd\n"); ret = 1; break; } cmdret = tmp; if (first) memcpy(cmdret, &cmd, sizeof(cmd)); else if (cmdret->opcode != cmd.opcode) { log_err("fio: fragment opcode mismatch (%d != %d)\n", cmdret->opcode, cmd.opcode); ret = 1; break; } if (!cmd.pdu_len) break; /* There's payload, get it */ pdu = (void *) cmdret->payload + pdu_offset; ret = fio_recv_data(sk, pdu, cmd.pdu_len, wait); if (ret) break; /* Verify payload crc */ crc = fio_crc16(pdu, cmd.pdu_len); if (crc != cmd.pdu_crc16) { log_err("fio: server bad crc on payload "); log_err("(got %x, wanted %x)\n", cmd.pdu_crc16, crc); ret = 1; break; } pdu_offset += cmd.pdu_len; if (!first) cmdret->pdu_len += cmd.pdu_len; first = 0; } while (cmd.flags & FIO_NET_CMD_F_MORE); if (ret) { free(cmdret); cmdret = NULL; } else if (cmdret) { /* zero-terminate text input */ if (cmdret->pdu_len) { if (cmdret->opcode == FIO_NET_CMD_TEXT) { struct cmd_text_pdu *__pdu = (struct cmd_text_pdu *) cmdret->payload; char *buf = (char *) __pdu->buf; buf[__pdu->buf_len] = '\0'; } else if (cmdret->opcode == FIO_NET_CMD_JOB) { struct cmd_job_pdu *__pdu = (struct cmd_job_pdu *) cmdret->payload; char *buf = (char *) __pdu->buf; int len = le32_to_cpu(__pdu->buf_len); buf[len] = '\0'; } } /* frag flag is internal */ cmdret->flags &= ~FIO_NET_CMD_F_MORE; } return cmdret; } static void add_reply(uint64_t tag, struct flist_head *list) { struct fio_net_cmd_reply *reply; reply = (struct fio_net_cmd_reply *) (uintptr_t) tag; flist_add_tail(&reply->list, list); } static uint64_t alloc_reply(uint64_t tag, uint16_t opcode) { struct fio_net_cmd_reply *reply; reply = calloc(1, sizeof(*reply)); INIT_FLIST_HEAD(&reply->list); fio_gettime(&reply->tv, NULL); reply->saved_tag = tag; reply->opcode = opcode; return (uintptr_t) reply; } static void free_reply(uint64_t tag) { struct fio_net_cmd_reply *reply; reply = (struct fio_net_cmd_reply *) (uintptr_t) tag; free(reply); } static void fio_net_cmd_crc_pdu(struct fio_net_cmd *cmd, const void *pdu) { uint32_t pdu_len; cmd->cmd_crc16 = __cpu_to_le16(fio_crc16(cmd, FIO_NET_CMD_CRC_SZ)); pdu_len = le32_to_cpu(cmd->pdu_len); cmd->pdu_crc16 = __cpu_to_le16(fio_crc16(pdu, pdu_len)); } static void fio_net_cmd_crc(struct fio_net_cmd *cmd) { fio_net_cmd_crc_pdu(cmd, cmd->payload); } int fio_net_send_cmd(int fd, uint16_t opcode, const void *buf, off_t size, uint64_t *tagptr, struct flist_head *list) { struct fio_net_cmd *cmd = NULL; size_t this_len, cur_len = 0; uint64_t tag; int ret; if (list) { assert(tagptr); tag = *tagptr = alloc_reply(*tagptr, opcode); } else tag = tagptr ? *tagptr : 0; do { this_len = size; if (this_len > FIO_SERVER_MAX_FRAGMENT_PDU) this_len = FIO_SERVER_MAX_FRAGMENT_PDU; if (!cmd || cur_len < sizeof(*cmd) + this_len) { if (cmd) free(cmd); cur_len = sizeof(*cmd) + this_len; cmd = malloc(cur_len); } fio_init_net_cmd(cmd, opcode, buf, this_len, tag); if (this_len < size) cmd->flags = __cpu_to_le32(FIO_NET_CMD_F_MORE); fio_net_cmd_crc(cmd); ret = fio_send_data(fd, cmd, sizeof(*cmd) + this_len); size -= this_len; buf += this_len; } while (!ret && size); if (list) { if (ret) free_reply(tag); else add_reply(tag, list); } if (cmd) free(cmd); return ret; } static struct sk_entry *fio_net_prep_cmd(uint16_t opcode, void *buf, size_t size, uint64_t *tagptr, int flags) { struct sk_entry *entry; entry = smalloc(sizeof(*entry)); INIT_FLIST_HEAD(&entry->next); entry->opcode = opcode; if (flags & SK_F_COPY) { entry->buf = smalloc(size); memcpy(entry->buf, buf, size); } else entry->buf = buf; entry->size = size; if (tagptr) entry->tag = *tagptr; else entry->tag = 0; entry->flags = flags; return entry; } static int handle_sk_entry(struct sk_out *sk_out, struct sk_entry *entry); static void fio_net_queue_entry(struct sk_entry *entry) { struct sk_out *sk_out = pthread_getspecific(sk_out_key); if (entry->flags & SK_F_INLINE) handle_sk_entry(sk_out, entry); else { sk_lock(sk_out); flist_add_tail(&entry->list, &sk_out->list); sk_unlock(sk_out); fio_mutex_up(&sk_out->wait); } } static int fio_net_queue_cmd(uint16_t opcode, void *buf, off_t size, uint64_t *tagptr, int flags) { struct sk_entry *entry; entry = fio_net_prep_cmd(opcode, buf, size, tagptr, flags); if (entry) { fio_net_queue_entry(entry); return 0; } return 1; } static int fio_net_send_simple_stack_cmd(int sk, uint16_t opcode, uint64_t tag) { struct fio_net_cmd cmd; fio_init_net_cmd(&cmd, opcode, NULL, 0, tag); fio_net_cmd_crc(&cmd); return fio_send_data(sk, &cmd, sizeof(cmd)); } /* * If 'list' is non-NULL, then allocate and store the sent command for * later verification. */ int fio_net_send_simple_cmd(int sk, uint16_t opcode, uint64_t tag, struct flist_head *list) { int ret; if (list) tag = alloc_reply(tag, opcode); ret = fio_net_send_simple_stack_cmd(sk, opcode, tag); if (ret) { if (list) free_reply(tag); return ret; } if (list) add_reply(tag, list); return 0; } static int fio_net_queue_quit(void) { dprint(FD_NET, "server: sending quit\n"); return fio_net_queue_cmd(FIO_NET_CMD_QUIT, NULL, 0, NULL, SK_F_SIMPLE); } int fio_net_send_quit(int sk) { dprint(FD_NET, "server: sending quit\n"); return fio_net_send_simple_cmd(sk, FIO_NET_CMD_QUIT, 0, NULL); } static int fio_net_send_ack(struct fio_net_cmd *cmd, int error, int signal) { struct cmd_end_pdu epdu; uint64_t tag = 0; if (cmd) tag = cmd->tag; epdu.error = __cpu_to_le32(error); epdu.signal = __cpu_to_le32(signal); return fio_net_queue_cmd(FIO_NET_CMD_STOP, &epdu, sizeof(epdu), &tag, SK_F_COPY); } static int fio_net_queue_stop(int error, int signal) { dprint(FD_NET, "server: sending stop (%d, %d)\n", error, signal); return fio_net_send_ack(NULL, error, signal); } static void fio_server_add_fork_item(pid_t pid, struct flist_head *list) { struct fio_fork_item *ffi; ffi = malloc(sizeof(*ffi)); ffi->exitval = 0; ffi->signal = 0; ffi->exited = 0; ffi->pid = pid; flist_add_tail(&ffi->list, list); } static void fio_server_add_conn_pid(struct flist_head *conn_list, pid_t pid) { dprint(FD_NET, "server: forked off connection job (pid=%u)\n", (int) pid); fio_server_add_fork_item(pid, conn_list); } static void fio_server_add_job_pid(struct flist_head *job_list, pid_t pid) { dprint(FD_NET, "server: forked off job job (pid=%u)\n", (int) pid); fio_server_add_fork_item(pid, job_list); } static void fio_server_check_fork_item(struct fio_fork_item *ffi) { int ret, status; ret = waitpid(ffi->pid, &status, WNOHANG); if (ret < 0) { if (errno == ECHILD) { log_err("fio: connection pid %u disappeared\n", (int) ffi->pid); ffi->exited = 1; } else log_err("fio: waitpid: %s\n", strerror(errno)); } else if (ret == ffi->pid) { if (WIFSIGNALED(status)) { ffi->signal = WTERMSIG(status); ffi->exited = 1; } if (WIFEXITED(status)) { if (WEXITSTATUS(status)) ffi->exitval = WEXITSTATUS(status); ffi->exited = 1; } } } static void fio_server_fork_item_done(struct fio_fork_item *ffi, bool stop) { dprint(FD_NET, "pid %u exited, sig=%u, exitval=%d\n", (int) ffi->pid, ffi->signal, ffi->exitval); /* * Fold STOP and QUIT... */ if (stop) { fio_net_queue_stop(ffi->exitval, ffi->signal); fio_net_queue_quit(); } flist_del(&ffi->list); free(ffi); } static void fio_server_check_fork_items(struct flist_head *list, bool stop) { struct flist_head *entry, *tmp; struct fio_fork_item *ffi; flist_for_each_safe(entry, tmp, list) { ffi = flist_entry(entry, struct fio_fork_item, list); fio_server_check_fork_item(ffi); if (ffi->exited) fio_server_fork_item_done(ffi, stop); } } static void fio_server_check_jobs(struct flist_head *job_list) { fio_server_check_fork_items(job_list, true); } static void fio_server_check_conns(struct flist_head *conn_list) { fio_server_check_fork_items(conn_list, false); } static int handle_load_file_cmd(struct fio_net_cmd *cmd) { struct cmd_load_file_pdu *pdu = (struct cmd_load_file_pdu *) cmd->payload; void *file_name = pdu->file; struct cmd_start_pdu spdu; dprint(FD_NET, "server: loading local file %s\n", (char *) file_name); pdu->name_len = le16_to_cpu(pdu->name_len); pdu->client_type = le16_to_cpu(pdu->client_type); if (parse_jobs_ini(file_name, 0, 0, pdu->client_type)) { fio_net_queue_quit(); return -1; } spdu.jobs = cpu_to_le32(thread_number); spdu.stat_outputs = cpu_to_le32(stat_number); fio_net_queue_cmd(FIO_NET_CMD_START, &spdu, sizeof(spdu), NULL, SK_F_COPY); return 0; } static int handle_run_cmd(struct sk_out *sk_out, struct flist_head *job_list, struct fio_net_cmd *cmd) { pid_t pid; int ret; sk_out_assign(sk_out); fio_time_init(); set_genesis_time(); pid = fork(); if (pid) { fio_server_add_job_pid(job_list, pid); return 0; } ret = fio_backend(sk_out); free_threads_shm(); sk_out_drop(); _exit(ret); } static int handle_job_cmd(struct fio_net_cmd *cmd) { struct cmd_job_pdu *pdu = (struct cmd_job_pdu *) cmd->payload; void *buf = pdu->buf; struct cmd_start_pdu spdu; pdu->buf_len = le32_to_cpu(pdu->buf_len); pdu->client_type = le32_to_cpu(pdu->client_type); if (parse_jobs_ini(buf, 1, 0, pdu->client_type)) { fio_net_queue_quit(); return -1; } spdu.jobs = cpu_to_le32(thread_number); spdu.stat_outputs = cpu_to_le32(stat_number); fio_net_queue_cmd(FIO_NET_CMD_START, &spdu, sizeof(spdu), NULL, SK_F_COPY); return 0; } static int handle_jobline_cmd(struct fio_net_cmd *cmd) { void *pdu = cmd->payload; struct cmd_single_line_pdu *cslp; struct cmd_line_pdu *clp; unsigned long offset; struct cmd_start_pdu spdu; char **argv; int i; clp = pdu; clp->lines = le16_to_cpu(clp->lines); clp->client_type = le16_to_cpu(clp->client_type); argv = malloc(clp->lines * sizeof(char *)); offset = sizeof(*clp); dprint(FD_NET, "server: %d command line args\n", clp->lines); for (i = 0; i < clp->lines; i++) { cslp = pdu + offset; argv[i] = (char *) cslp->text; offset += sizeof(*cslp) + le16_to_cpu(cslp->len); dprint(FD_NET, "server: %d: %s\n", i, argv[i]); } if (parse_cmd_line(clp->lines, argv, clp->client_type)) { fio_net_queue_quit(); free(argv); return -1; } free(argv); spdu.jobs = cpu_to_le32(thread_number); spdu.stat_outputs = cpu_to_le32(stat_number); fio_net_queue_cmd(FIO_NET_CMD_START, &spdu, sizeof(spdu), NULL, SK_F_COPY); return 0; } static int handle_probe_cmd(struct fio_net_cmd *cmd) { struct cmd_client_probe_pdu *pdu = (struct cmd_client_probe_pdu *) cmd->payload; struct cmd_probe_reply_pdu probe; uint64_t tag = cmd->tag; dprint(FD_NET, "server: sending probe reply\n"); strcpy(me, (char *) pdu->server); memset(&probe, 0, sizeof(probe)); gethostname((char *) probe.hostname, sizeof(probe.hostname)); #ifdef CONFIG_BIG_ENDIAN probe.bigendian = 1; #endif strncpy((char *) probe.fio_version, fio_version_string, sizeof(probe.fio_version)); probe.os = FIO_OS; probe.arch = FIO_ARCH; probe.bpp = sizeof(void *); probe.cpus = __cpu_to_le32(cpus_online()); /* * If the client supports compression and we do too, then enable it */ if (has_zlib && le64_to_cpu(pdu->flags) & FIO_PROBE_FLAG_ZLIB) { probe.flags = __cpu_to_le64(FIO_PROBE_FLAG_ZLIB); use_zlib = 1; } else { probe.flags = 0; use_zlib = 0; } return fio_net_queue_cmd(FIO_NET_CMD_PROBE, &probe, sizeof(probe), &tag, SK_F_COPY); } static int handle_send_eta_cmd(struct fio_net_cmd *cmd) { struct jobs_eta *je; uint64_t tag = cmd->tag; size_t size; int i; dprint(FD_NET, "server sending status\n"); /* * Fake ETA return if we don't have a local one, otherwise the client * will end up timing out waiting for a response to the ETA request */ je = get_jobs_eta(true, &size); if (!je) { size = sizeof(*je); je = calloc(1, size); } else { je->nr_running = cpu_to_le32(je->nr_running); je->nr_ramp = cpu_to_le32(je->nr_ramp); je->nr_pending = cpu_to_le32(je->nr_pending); je->nr_setting_up = cpu_to_le32(je->nr_setting_up); je->files_open = cpu_to_le32(je->files_open); for (i = 0; i < DDIR_RWDIR_CNT; i++) { je->m_rate[i] = cpu_to_le64(je->m_rate[i]); je->t_rate[i] = cpu_to_le64(je->t_rate[i]); je->m_iops[i] = cpu_to_le32(je->m_iops[i]); je->t_iops[i] = cpu_to_le32(je->t_iops[i]); je->rate[i] = cpu_to_le64(je->rate[i]); je->iops[i] = cpu_to_le32(je->iops[i]); } je->elapsed_sec = cpu_to_le64(je->elapsed_sec); je->eta_sec = cpu_to_le64(je->eta_sec); je->nr_threads = cpu_to_le32(je->nr_threads); je->is_pow2 = cpu_to_le32(je->is_pow2); je->unit_base = cpu_to_le32(je->unit_base); } fio_net_queue_cmd(FIO_NET_CMD_ETA, je, size, &tag, SK_F_FREE); return 0; } static int send_update_job_reply(uint64_t __tag, int error) { uint64_t tag = __tag; uint32_t pdu_error; pdu_error = __cpu_to_le32(error); return fio_net_queue_cmd(FIO_NET_CMD_UPDATE_JOB, &pdu_error, sizeof(pdu_error), &tag, SK_F_COPY); } static int handle_update_job_cmd(struct fio_net_cmd *cmd) { struct cmd_add_job_pdu *pdu = (struct cmd_add_job_pdu *) cmd->payload; struct thread_data *td; uint32_t tnumber; tnumber = le32_to_cpu(pdu->thread_number); dprint(FD_NET, "server: updating options for job %u\n", tnumber); if (!tnumber || tnumber > thread_number) { send_update_job_reply(cmd->tag, ENODEV); return 0; } td = &threads[tnumber - 1]; convert_thread_options_to_cpu(&td->o, &pdu->top); send_update_job_reply(cmd->tag, 0); return 0; } static int handle_trigger_cmd(struct fio_net_cmd *cmd) { struct cmd_vtrigger_pdu *pdu = (struct cmd_vtrigger_pdu *) cmd->payload; char *buf = (char *) pdu->cmd; struct all_io_list *rep; size_t sz; pdu->len = le16_to_cpu(pdu->len); buf[pdu->len] = '\0'; rep = get_all_io_list(IO_LIST_ALL, &sz); if (!rep) { struct all_io_list state; state.threads = cpu_to_le64((uint64_t) 0); fio_net_queue_cmd(FIO_NET_CMD_VTRIGGER, &state, sizeof(state), NULL, SK_F_COPY | SK_F_INLINE); } else fio_net_queue_cmd(FIO_NET_CMD_VTRIGGER, rep, sz, NULL, SK_F_FREE | SK_F_INLINE); exec_trigger(buf); return 0; } static int handle_command(struct sk_out *sk_out, struct flist_head *job_list, struct fio_net_cmd *cmd) { int ret; dprint(FD_NET, "server: got op [%s], pdu=%u, tag=%llx\n", fio_server_op(cmd->opcode), cmd->pdu_len, (unsigned long long) cmd->tag); switch (cmd->opcode) { case FIO_NET_CMD_QUIT: fio_terminate_threads(TERMINATE_ALL); ret = 0; break; case FIO_NET_CMD_EXIT: exit_backend = 1; return -1; case FIO_NET_CMD_LOAD_FILE: ret = handle_load_file_cmd(cmd); break; case FIO_NET_CMD_JOB: ret = handle_job_cmd(cmd); break; case FIO_NET_CMD_JOBLINE: ret = handle_jobline_cmd(cmd); break; case FIO_NET_CMD_PROBE: ret = handle_probe_cmd(cmd); break; case FIO_NET_CMD_SEND_ETA: ret = handle_send_eta_cmd(cmd); break; case FIO_NET_CMD_RUN: ret = handle_run_cmd(sk_out, job_list, cmd); break; case FIO_NET_CMD_UPDATE_JOB: ret = handle_update_job_cmd(cmd); break; case FIO_NET_CMD_VTRIGGER: ret = handle_trigger_cmd(cmd); break; case FIO_NET_CMD_SENDFILE: { struct cmd_sendfile_reply *in; struct cmd_reply *rep; rep = (struct cmd_reply *) (uintptr_t) cmd->tag; in = (struct cmd_sendfile_reply *) cmd->payload; in->size = le32_to_cpu(in->size); in->error = le32_to_cpu(in->error); if (in->error) { ret = 1; rep->error = in->error; } else { ret = 0; rep->data = smalloc(in->size); if (!rep->data) { ret = 1; rep->error = ENOMEM; } else { rep->size = in->size; memcpy(rep->data, in->data, in->size); } } fio_mutex_up(&rep->lock); break; } default: log_err("fio: unknown opcode: %s\n", fio_server_op(cmd->opcode)); ret = 1; } return ret; } /* * Send a command with a separate PDU, not inlined in the command */ static int fio_send_cmd_ext_pdu(int sk, uint16_t opcode, const void *buf, off_t size, uint64_t tag, uint32_t flags) { struct fio_net_cmd cmd; struct iovec iov[2]; size_t this_len; int ret; iov[0].iov_base = (void *) &cmd; iov[0].iov_len = sizeof(cmd); do { uint32_t this_flags = flags; this_len = size; if (this_len > FIO_SERVER_MAX_FRAGMENT_PDU) this_len = FIO_SERVER_MAX_FRAGMENT_PDU; if (this_len < size) this_flags |= FIO_NET_CMD_F_MORE; __fio_init_net_cmd(&cmd, opcode, this_len, tag); cmd.flags = __cpu_to_le32(this_flags); fio_net_cmd_crc_pdu(&cmd, buf); iov[1].iov_base = (void *) buf; iov[1].iov_len = this_len; ret = fio_sendv_data(sk, iov, 2); size -= this_len; buf += this_len; } while (!ret && size); return ret; } static void finish_entry(struct sk_entry *entry) { if (entry->flags & SK_F_FREE) free(entry->buf); else if (entry->flags & SK_F_COPY) sfree(entry->buf); sfree(entry); } static void entry_set_flags(struct sk_entry *entry, struct flist_head *list, unsigned int *flags) { if (!flist_empty(list)) *flags = FIO_NET_CMD_F_MORE; else *flags = 0; } static int send_vec_entry(struct sk_out *sk_out, struct sk_entry *first) { unsigned int flags; int ret; entry_set_flags(first, &first->next, &flags); ret = fio_send_cmd_ext_pdu(sk_out->sk, first->opcode, first->buf, first->size, first->tag, flags); while (!flist_empty(&first->next)) { struct sk_entry *next; next = flist_first_entry(&first->next, struct sk_entry, list); flist_del_init(&next->list); entry_set_flags(next, &first->next, &flags); ret += fio_send_cmd_ext_pdu(sk_out->sk, next->opcode, next->buf, next->size, next->tag, flags); finish_entry(next); } return ret; } static int handle_sk_entry(struct sk_out *sk_out, struct sk_entry *entry) { int ret; fio_mutex_down(&sk_out->xmit); if (entry->flags & SK_F_VEC) ret = send_vec_entry(sk_out, entry); else if (entry->flags & SK_F_SIMPLE) { ret = fio_net_send_simple_cmd(sk_out->sk, entry->opcode, entry->tag, NULL); } else { ret = fio_net_send_cmd(sk_out->sk, entry->opcode, entry->buf, entry->size, &entry->tag, NULL); } fio_mutex_up(&sk_out->xmit); if (ret) log_err("fio: failed handling cmd %s\n", fio_server_op(entry->opcode)); finish_entry(entry); return ret; } static int handle_xmits(struct sk_out *sk_out) { struct sk_entry *entry; FLIST_HEAD(list); int ret = 0; sk_lock(sk_out); if (flist_empty(&sk_out->list)) { sk_unlock(sk_out); return 0; } flist_splice_init(&sk_out->list, &list); sk_unlock(sk_out); while (!flist_empty(&list)) { entry = flist_entry(list.next, struct sk_entry, list); flist_del(&entry->list); ret += handle_sk_entry(sk_out, entry); } return ret; } static int handle_connection(struct sk_out *sk_out) { struct fio_net_cmd *cmd = NULL; FLIST_HEAD(job_list); int ret = 0; reset_fio_state(); /* read forever */ while (!exit_backend) { struct pollfd pfd = { .fd = sk_out->sk, .events = POLLIN, }; ret = 0; do { int timeout = 1000; if (!flist_empty(&job_list)) timeout = 100; handle_xmits(sk_out); ret = poll(&pfd, 1, 0); if (ret < 0) { if (errno == EINTR) break; log_err("fio: poll: %s\n", strerror(errno)); break; } else if (!ret) { fio_server_check_jobs(&job_list); fio_mutex_down_timeout(&sk_out->wait, timeout); continue; } if (pfd.revents & POLLIN) break; if (pfd.revents & (POLLERR|POLLHUP)) { ret = 1; break; } } while (!exit_backend); fio_server_check_jobs(&job_list); if (ret < 0) break; cmd = fio_net_recv_cmd(sk_out->sk, true); if (!cmd) { ret = -1; break; } ret = handle_command(sk_out, &job_list, cmd); if (ret) break; free(cmd); cmd = NULL; } if (cmd) free(cmd); handle_xmits(sk_out); close(sk_out->sk); sk_out->sk = -1; __sk_out_drop(sk_out); _exit(ret); } /* get the address on this host bound by the input socket, * whether it is ipv6 or ipv4 */ static int get_my_addr_str(int sk) { struct sockaddr_in6 myaddr6 = { 0, }; struct sockaddr_in myaddr4 = { 0, }; struct sockaddr *sockaddr_p; char *net_addr; socklen_t len; int ret; if (use_ipv6) { len = sizeof(myaddr6); sockaddr_p = (struct sockaddr * )&myaddr6; net_addr = (char * )&myaddr6.sin6_addr; } else { len = sizeof(myaddr4); sockaddr_p = (struct sockaddr * )&myaddr4; net_addr = (char * )&myaddr4.sin_addr; } ret = getsockname(sk, sockaddr_p, &len); if (ret) { log_err("fio: getsockaddr: %s\n", strerror(errno)); return -1; } if (!inet_ntop(use_ipv6?AF_INET6:AF_INET, net_addr, client_sockaddr_str, INET6_ADDRSTRLEN - 1)) { log_err("inet_ntop: failed to convert addr to string\n"); return -1; } dprint(FD_NET, "fio server bound to addr %s\n", client_sockaddr_str); return 0; } static int accept_loop(int listen_sk) { struct sockaddr_in addr; struct sockaddr_in6 addr6; socklen_t len = use_ipv6 ? sizeof(addr6) : sizeof(addr); struct pollfd pfd; int ret = 0, sk, exitval = 0; FLIST_HEAD(conn_list); dprint(FD_NET, "server enter accept loop\n"); fio_set_fd_nonblocking(listen_sk, "server"); while (!exit_backend) { struct sk_out *sk_out; const char *from; char buf[64]; pid_t pid; pfd.fd = listen_sk; pfd.events = POLLIN; do { int timeout = 1000; if (!flist_empty(&conn_list)) timeout = 100; ret = poll(&pfd, 1, timeout); if (ret < 0) { if (errno == EINTR) break; log_err("fio: poll: %s\n", strerror(errno)); break; } else if (!ret) { fio_server_check_conns(&conn_list); continue; } if (pfd.revents & POLLIN) break; } while (!exit_backend); fio_server_check_conns(&conn_list); if (exit_backend || ret < 0) break; if (use_ipv6) sk = accept(listen_sk, (struct sockaddr *) &addr6, &len); else sk = accept(listen_sk, (struct sockaddr *) &addr, &len); if (sk < 0) { log_err("fio: accept: %s\n", strerror(errno)); return -1; } if (use_ipv6) from = inet_ntop(AF_INET6, (struct sockaddr *) &addr6.sin6_addr, buf, sizeof(buf)); else from = inet_ntop(AF_INET, (struct sockaddr *) &addr.sin_addr, buf, sizeof(buf)); dprint(FD_NET, "server: connect from %s\n", from); sk_out = smalloc(sizeof(*sk_out)); sk_out->sk = sk; INIT_FLIST_HEAD(&sk_out->list); __fio_mutex_init(&sk_out->lock, FIO_MUTEX_UNLOCKED); __fio_mutex_init(&sk_out->wait, FIO_MUTEX_LOCKED); __fio_mutex_init(&sk_out->xmit, FIO_MUTEX_UNLOCKED); pid = fork(); if (pid) { close(sk); fio_server_add_conn_pid(&conn_list, pid); continue; } /* if error, it's already logged, non-fatal */ get_my_addr_str(sk); /* * Assign sk_out here, it'll be dropped in handle_connection() * since that function calls _exit() when done */ sk_out_assign(sk_out); handle_connection(sk_out); } return exitval; } int fio_server_text_output(int level, const char *buf, size_t len) { struct sk_out *sk_out = pthread_getspecific(sk_out_key); struct cmd_text_pdu *pdu; unsigned int tlen; struct timeval tv; if (!sk_out || sk_out->sk == -1) return -1; tlen = sizeof(*pdu) + len; pdu = malloc(tlen); pdu->level = __cpu_to_le32(level); pdu->buf_len = __cpu_to_le32(len); gettimeofday(&tv, NULL); pdu->log_sec = __cpu_to_le64(tv.tv_sec); pdu->log_usec = __cpu_to_le64(tv.tv_usec); memcpy(pdu->buf, buf, len); fio_net_queue_cmd(FIO_NET_CMD_TEXT, pdu, tlen, NULL, SK_F_COPY); free(pdu); return len; } static void convert_io_stat(struct io_stat *dst, struct io_stat *src) { dst->max_val = cpu_to_le64(src->max_val); dst->min_val = cpu_to_le64(src->min_val); dst->samples = cpu_to_le64(src->samples); /* * Encode to IEEE 754 for network transfer */ dst->mean.u.i = cpu_to_le64(fio_double_to_uint64(src->mean.u.f)); dst->S.u.i = cpu_to_le64(fio_double_to_uint64(src->S.u.f)); } static void convert_gs(struct group_run_stats *dst, struct group_run_stats *src) { int i; for (i = 0; i < DDIR_RWDIR_CNT; i++) { dst->max_run[i] = cpu_to_le64(src->max_run[i]); dst->min_run[i] = cpu_to_le64(src->min_run[i]); dst->max_bw[i] = cpu_to_le64(src->max_bw[i]); dst->min_bw[i] = cpu_to_le64(src->min_bw[i]); dst->iobytes[i] = cpu_to_le64(src->iobytes[i]); dst->agg[i] = cpu_to_le64(src->agg[i]); } dst->kb_base = cpu_to_le32(src->kb_base); dst->unit_base = cpu_to_le32(src->unit_base); dst->groupid = cpu_to_le32(src->groupid); dst->unified_rw_rep = cpu_to_le32(src->unified_rw_rep); } /* * Send a CMD_TS, which packs struct thread_stat and group_run_stats * into a single payload. */ void fio_server_send_ts(struct thread_stat *ts, struct group_run_stats *rs) { struct cmd_ts_pdu p; int i, j; void *ss_buf; uint64_t *ss_iops, *ss_bw; dprint(FD_NET, "server sending end stats\n"); memset(&p, 0, sizeof(p)); strncpy(p.ts.name, ts->name, FIO_JOBNAME_SIZE - 1); strncpy(p.ts.verror, ts->verror, FIO_VERROR_SIZE - 1); strncpy(p.ts.description, ts->description, FIO_JOBDESC_SIZE - 1); p.ts.error = cpu_to_le32(ts->error); p.ts.thread_number = cpu_to_le32(ts->thread_number); p.ts.groupid = cpu_to_le32(ts->groupid); p.ts.pid = cpu_to_le32(ts->pid); p.ts.members = cpu_to_le32(ts->members); p.ts.unified_rw_rep = cpu_to_le32(ts->unified_rw_rep); for (i = 0; i < DDIR_RWDIR_CNT; i++) { convert_io_stat(&p.ts.clat_stat[i], &ts->clat_stat[i]); convert_io_stat(&p.ts.slat_stat[i], &ts->slat_stat[i]); convert_io_stat(&p.ts.lat_stat[i], &ts->lat_stat[i]); convert_io_stat(&p.ts.bw_stat[i], &ts->bw_stat[i]); } p.ts.usr_time = cpu_to_le64(ts->usr_time); p.ts.sys_time = cpu_to_le64(ts->sys_time); p.ts.ctx = cpu_to_le64(ts->ctx); p.ts.minf = cpu_to_le64(ts->minf); p.ts.majf = cpu_to_le64(ts->majf); p.ts.clat_percentiles = cpu_to_le64(ts->clat_percentiles); p.ts.percentile_precision = cpu_to_le64(ts->percentile_precision); for (i = 0; i < FIO_IO_U_LIST_MAX_LEN; i++) { fio_fp64_t *src = &ts->percentile_list[i]; fio_fp64_t *dst = &p.ts.percentile_list[i]; dst->u.i = cpu_to_le64(fio_double_to_uint64(src->u.f)); } for (i = 0; i < FIO_IO_U_MAP_NR; i++) { p.ts.io_u_map[i] = cpu_to_le32(ts->io_u_map[i]); p.ts.io_u_submit[i] = cpu_to_le32(ts->io_u_submit[i]); p.ts.io_u_complete[i] = cpu_to_le32(ts->io_u_complete[i]); } for (i = 0; i < FIO_IO_U_LAT_U_NR; i++) p.ts.io_u_lat_u[i] = cpu_to_le32(ts->io_u_lat_u[i]); for (i = 0; i < FIO_IO_U_LAT_M_NR; i++) p.ts.io_u_lat_m[i] = cpu_to_le32(ts->io_u_lat_m[i]); for (i = 0; i < DDIR_RWDIR_CNT; i++) for (j = 0; j < FIO_IO_U_PLAT_NR; j++) p.ts.io_u_plat[i][j] = cpu_to_le32(ts->io_u_plat[i][j]); for (i = 0; i < DDIR_RWDIR_CNT; i++) { p.ts.total_io_u[i] = cpu_to_le64(ts->total_io_u[i]); p.ts.short_io_u[i] = cpu_to_le64(ts->short_io_u[i]); p.ts.drop_io_u[i] = cpu_to_le64(ts->drop_io_u[i]); } p.ts.total_submit = cpu_to_le64(ts->total_submit); p.ts.total_complete = cpu_to_le64(ts->total_complete); for (i = 0; i < DDIR_RWDIR_CNT; i++) { p.ts.io_bytes[i] = cpu_to_le64(ts->io_bytes[i]); p.ts.runtime[i] = cpu_to_le64(ts->runtime[i]); } p.ts.total_run_time = cpu_to_le64(ts->total_run_time); p.ts.continue_on_error = cpu_to_le16(ts->continue_on_error); p.ts.total_err_count = cpu_to_le64(ts->total_err_count); p.ts.first_error = cpu_to_le32(ts->first_error); p.ts.kb_base = cpu_to_le32(ts->kb_base); p.ts.unit_base = cpu_to_le32(ts->unit_base); p.ts.latency_depth = cpu_to_le32(ts->latency_depth); p.ts.latency_target = cpu_to_le64(ts->latency_target); p.ts.latency_window = cpu_to_le64(ts->latency_window); p.ts.latency_percentile.u.i = cpu_to_le64(fio_double_to_uint64(ts->latency_percentile.u.f)); p.ts.nr_block_infos = cpu_to_le64(ts->nr_block_infos); for (i = 0; i < p.ts.nr_block_infos; i++) p.ts.block_infos[i] = cpu_to_le32(ts->block_infos[i]); p.ts.ss_dur = cpu_to_le64(ts->ss_dur); p.ts.ss_state = cpu_to_le32(ts->ss_state); p.ts.ss_head = cpu_to_le32(ts->ss_head); p.ts.ss_limit.u.i = cpu_to_le64(fio_double_to_uint64(ts->ss_limit.u.f)); p.ts.ss_slope.u.i = cpu_to_le64(fio_double_to_uint64(ts->ss_slope.u.f)); p.ts.ss_deviation.u.i = cpu_to_le64(fio_double_to_uint64(ts->ss_deviation.u.f)); p.ts.ss_criterion.u.i = cpu_to_le64(fio_double_to_uint64(ts->ss_criterion.u.f)); convert_gs(&p.rs, rs); dprint(FD_NET, "ts->ss_state = %d\n", ts->ss_state); if (ts->ss_state & __FIO_SS_DATA) { dprint(FD_NET, "server sending steadystate ring buffers\n"); ss_buf = malloc(sizeof(p) + 2*ts->ss_dur*sizeof(uint64_t)); memcpy(ss_buf, &p, sizeof(p)); ss_iops = (uint64_t *) ((struct cmd_ts_pdu *)ss_buf + 1); ss_bw = ss_iops + (int) ts->ss_dur; for (i = 0; i < ts->ss_dur; i++) { ss_iops[i] = cpu_to_le64(ts->ss_iops_data[i]); ss_bw[i] = cpu_to_le64(ts->ss_bw_data[i]); } fio_net_queue_cmd(FIO_NET_CMD_TS, ss_buf, sizeof(p) + 2*ts->ss_dur*sizeof(uint64_t), NULL, SK_F_COPY); free(ss_buf); } else fio_net_queue_cmd(FIO_NET_CMD_TS, &p, sizeof(p), NULL, SK_F_COPY); } void fio_server_send_gs(struct group_run_stats *rs) { struct group_run_stats gs; dprint(FD_NET, "server sending group run stats\n"); convert_gs(&gs, rs); fio_net_queue_cmd(FIO_NET_CMD_GS, &gs, sizeof(gs), NULL, SK_F_COPY); } void fio_server_send_job_options(struct flist_head *opt_list, unsigned int groupid) { struct cmd_job_option pdu; struct flist_head *entry; if (flist_empty(opt_list)) return; flist_for_each(entry, opt_list) { struct print_option *p; size_t len; p = flist_entry(entry, struct print_option, list); memset(&pdu, 0, sizeof(pdu)); if (groupid == -1U) { pdu.global = __cpu_to_le16(1); pdu.groupid = 0; } else { pdu.global = 0; pdu.groupid = cpu_to_le32(groupid); } len = strlen(p->name); if (len >= sizeof(pdu.name)) { len = sizeof(pdu.name) - 1; pdu.truncated = __cpu_to_le16(1); } memcpy(pdu.name, p->name, len); if (p->value) { len = strlen(p->value); if (len >= sizeof(pdu.value)) { len = sizeof(pdu.value) - 1; pdu.truncated = __cpu_to_le16(1); } memcpy(pdu.value, p->value, len); } fio_net_queue_cmd(FIO_NET_CMD_JOB_OPT, &pdu, sizeof(pdu), NULL, SK_F_COPY); } } static void convert_agg(struct disk_util_agg *dst, struct disk_util_agg *src) { int i; for (i = 0; i < 2; i++) { dst->ios[i] = cpu_to_le64(src->ios[i]); dst->merges[i] = cpu_to_le64(src->merges[i]); dst->sectors[i] = cpu_to_le64(src->sectors[i]); dst->ticks[i] = cpu_to_le64(src->ticks[i]); } dst->io_ticks = cpu_to_le64(src->io_ticks); dst->time_in_queue = cpu_to_le64(src->time_in_queue); dst->slavecount = cpu_to_le32(src->slavecount); dst->max_util.u.i = cpu_to_le64(fio_double_to_uint64(src->max_util.u.f)); } static void convert_dus(struct disk_util_stat *dst, struct disk_util_stat *src) { int i; dst->name[FIO_DU_NAME_SZ - 1] = '\0'; strncpy((char *) dst->name, (char *) src->name, FIO_DU_NAME_SZ - 1); for (i = 0; i < 2; i++) { dst->s.ios[i] = cpu_to_le64(src->s.ios[i]); dst->s.merges[i] = cpu_to_le64(src->s.merges[i]); dst->s.sectors[i] = cpu_to_le64(src->s.sectors[i]); dst->s.ticks[i] = cpu_to_le64(src->s.ticks[i]); } dst->s.io_ticks = cpu_to_le64(src->s.io_ticks); dst->s.time_in_queue = cpu_to_le64(src->s.time_in_queue); dst->s.msec = cpu_to_le64(src->s.msec); } void fio_server_send_du(void) { struct disk_util *du; struct flist_head *entry; struct cmd_du_pdu pdu; dprint(FD_NET, "server: sending disk_util %d\n", !flist_empty(&disk_list)); memset(&pdu, 0, sizeof(pdu)); flist_for_each(entry, &disk_list) { du = flist_entry(entry, struct disk_util, list); convert_dus(&pdu.dus, &du->dus); convert_agg(&pdu.agg, &du->agg); fio_net_queue_cmd(FIO_NET_CMD_DU, &pdu, sizeof(pdu), NULL, SK_F_COPY); } } #ifdef CONFIG_ZLIB static inline void __fio_net_prep_tail(z_stream *stream, void *out_pdu, struct sk_entry **last_entry, struct sk_entry *first) { unsigned int this_len = FIO_SERVER_MAX_FRAGMENT_PDU - stream->avail_out; *last_entry = fio_net_prep_cmd(FIO_NET_CMD_IOLOG, out_pdu, this_len, NULL, SK_F_VEC | SK_F_INLINE | SK_F_FREE); flist_add_tail(&(*last_entry)->list, &first->next); } /* * Deflates the next input given, creating as many new packets in the * linked list as necessary. */ static int __deflate_pdu_buffer(void *next_in, unsigned int next_sz, void **out_pdu, struct sk_entry **last_entry, z_stream *stream, struct sk_entry *first) { int ret; stream->next_in = next_in; stream->avail_in = next_sz; do { if (! stream->avail_out) { __fio_net_prep_tail(stream, *out_pdu, last_entry, first); *out_pdu = malloc(FIO_SERVER_MAX_FRAGMENT_PDU); stream->avail_out = FIO_SERVER_MAX_FRAGMENT_PDU; stream->next_out = *out_pdu; } ret = deflate(stream, Z_BLOCK); if (ret < 0) { free(*out_pdu); return 1; } } while (stream->avail_in); return 0; } static int __fio_append_iolog_gz_hist(struct sk_entry *first, struct io_log *log, struct io_logs *cur_log, z_stream *stream) { struct sk_entry *entry; void *out_pdu; int ret, i, j; int sample_sz = log_entry_sz(log); out_pdu = malloc(FIO_SERVER_MAX_FRAGMENT_PDU); stream->avail_out = FIO_SERVER_MAX_FRAGMENT_PDU; stream->next_out = out_pdu; for (i = 0; i < cur_log->nr_samples; i++) { struct io_sample *s; struct io_u_plat_entry *cur_plat_entry, *prev_plat_entry; unsigned int *cur_plat, *prev_plat; s = get_sample(log, cur_log, i); ret = __deflate_pdu_buffer(s, sample_sz, &out_pdu, &entry, stream, first); if (ret) return ret; /* Do the subtraction on server side so that client doesn't have to * reconstruct our linked list from packets. */ cur_plat_entry = s->data.plat_entry; prev_plat_entry = flist_first_entry(&cur_plat_entry->list, struct io_u_plat_entry, list); cur_plat = cur_plat_entry->io_u_plat; prev_plat = prev_plat_entry->io_u_plat; for (j = 0; j < FIO_IO_U_PLAT_NR; j++) { cur_plat[j] -= prev_plat[j]; } flist_del(&prev_plat_entry->list); free(prev_plat_entry); ret = __deflate_pdu_buffer(cur_plat_entry, sizeof(*cur_plat_entry), &out_pdu, &entry, stream, first); if (ret) return ret; } __fio_net_prep_tail(stream, out_pdu, &entry, first); return 0; } static int __fio_append_iolog_gz(struct sk_entry *first, struct io_log *log, struct io_logs *cur_log, z_stream *stream) { unsigned int this_len; void *out_pdu; int ret; if (log->log_type == IO_LOG_TYPE_HIST) return __fio_append_iolog_gz_hist(first, log, cur_log, stream); stream->next_in = (void *) cur_log->log; stream->avail_in = cur_log->nr_samples * log_entry_sz(log); do { struct sk_entry *entry; /* * Dirty - since the log is potentially huge, compress it into * FIO_SERVER_MAX_FRAGMENT_PDU chunks and let the receiving * side defragment it. */ out_pdu = malloc(FIO_SERVER_MAX_FRAGMENT_PDU); stream->avail_out = FIO_SERVER_MAX_FRAGMENT_PDU; stream->next_out = out_pdu; ret = deflate(stream, Z_BLOCK); /* may be Z_OK, or Z_STREAM_END */ if (ret < 0) { free(out_pdu); return 1; } this_len = FIO_SERVER_MAX_FRAGMENT_PDU - stream->avail_out; entry = fio_net_prep_cmd(FIO_NET_CMD_IOLOG, out_pdu, this_len, NULL, SK_F_VEC | SK_F_INLINE | SK_F_FREE); flist_add_tail(&entry->list, &first->next); } while (stream->avail_in); return 0; } static int fio_append_iolog_gz(struct sk_entry *first, struct io_log *log) { int ret = 0; z_stream stream; memset(&stream, 0, sizeof(stream)); stream.zalloc = Z_NULL; stream.zfree = Z_NULL; stream.opaque = Z_NULL; if (deflateInit(&stream, Z_DEFAULT_COMPRESSION) != Z_OK) return 1; while (!flist_empty(&log->io_logs)) { struct io_logs *cur_log; cur_log = flist_first_entry(&log->io_logs, struct io_logs, list); flist_del_init(&cur_log->list); ret = __fio_append_iolog_gz(first, log, cur_log, &stream); if (ret) break; } ret = deflate(&stream, Z_FINISH); while (ret != Z_STREAM_END) { struct sk_entry *entry; unsigned int this_len; void *out_pdu; out_pdu = malloc(FIO_SERVER_MAX_FRAGMENT_PDU); stream.avail_out = FIO_SERVER_MAX_FRAGMENT_PDU; stream.next_out = out_pdu; ret = deflate(&stream, Z_FINISH); /* may be Z_OK, or Z_STREAM_END */ if (ret < 0) { free(out_pdu); break; } this_len = FIO_SERVER_MAX_FRAGMENT_PDU - stream.avail_out; entry = fio_net_prep_cmd(FIO_NET_CMD_IOLOG, out_pdu, this_len, NULL, SK_F_VEC | SK_F_INLINE | SK_F_FREE); flist_add_tail(&entry->list, &first->next); } while (ret != Z_STREAM_END); ret = deflateEnd(&stream); if (ret == Z_OK) return 0; return 1; } #else static int fio_append_iolog_gz(struct sk_entry *first, struct io_log *log) { return 1; } #endif static int fio_append_gz_chunks(struct sk_entry *first, struct io_log *log) { struct sk_entry *entry; struct flist_head *node; pthread_mutex_lock(&log->chunk_lock); flist_for_each(node, &log->chunk_list) { struct iolog_compress *c; c = flist_entry(node, struct iolog_compress, list); entry = fio_net_prep_cmd(FIO_NET_CMD_IOLOG, c->buf, c->len, NULL, SK_F_VEC | SK_F_INLINE); flist_add_tail(&entry->list, &first->next); } pthread_mutex_unlock(&log->chunk_lock); return 0; } static int fio_append_text_log(struct sk_entry *first, struct io_log *log) { struct sk_entry *entry; while (!flist_empty(&log->io_logs)) { struct io_logs *cur_log; size_t size; cur_log = flist_first_entry(&log->io_logs, struct io_logs, list); flist_del_init(&cur_log->list); size = cur_log->nr_samples * log_entry_sz(log); entry = fio_net_prep_cmd(FIO_NET_CMD_IOLOG, cur_log->log, size, NULL, SK_F_VEC | SK_F_INLINE); flist_add_tail(&entry->list, &first->next); } return 0; } int fio_send_iolog(struct thread_data *td, struct io_log *log, const char *name) { struct cmd_iolog_pdu pdu; struct sk_entry *first; struct flist_head *entry; int ret = 0; pdu.nr_samples = cpu_to_le64(iolog_nr_samples(log)); pdu.thread_number = cpu_to_le32(td->thread_number); pdu.log_type = cpu_to_le32(log->log_type); pdu.log_hist_coarseness = cpu_to_le32(log->hist_coarseness); if (!flist_empty(&log->chunk_list)) pdu.compressed = __cpu_to_le32(STORE_COMPRESSED); else if (use_zlib) pdu.compressed = __cpu_to_le32(XMIT_COMPRESSED); else pdu.compressed = 0; strncpy((char *) pdu.name, name, FIO_NET_NAME_MAX); pdu.name[FIO_NET_NAME_MAX - 1] = '\0'; /* * We can't do this for a pre-compressed log, but for that case, * log->nr_samples is zero anyway. */ flist_for_each(entry, &log->io_logs) { struct io_logs *cur_log; int i; cur_log = flist_entry(entry, struct io_logs, list); for (i = 0; i < cur_log->nr_samples; i++) { struct io_sample *s = get_sample(log, cur_log, i); s->time = cpu_to_le64(s->time); s->data.val = cpu_to_le64(s->data.val); s->__ddir = cpu_to_le32(s->__ddir); s->bs = cpu_to_le32(s->bs); if (log->log_offset) { struct io_sample_offset *so = (void *) s; so->offset = cpu_to_le64(so->offset); } } } /* * Assemble header entry first */ first = fio_net_prep_cmd(FIO_NET_CMD_IOLOG, &pdu, sizeof(pdu), NULL, SK_F_VEC | SK_F_INLINE | SK_F_COPY); /* * Now append actual log entries. If log compression was enabled on * the job, just send out the compressed chunks directly. If we * have a plain log, compress if we can, then send. Otherwise, send * the plain text output. */ if (!flist_empty(&log->chunk_list)) ret = fio_append_gz_chunks(first, log); else if (use_zlib) ret = fio_append_iolog_gz(first, log); else ret = fio_append_text_log(first, log); fio_net_queue_entry(first); return ret; } void fio_server_send_add_job(struct thread_data *td) { struct cmd_add_job_pdu pdu; memset(&pdu, 0, sizeof(pdu)); pdu.thread_number = cpu_to_le32(td->thread_number); pdu.groupid = cpu_to_le32(td->groupid); convert_thread_options_to_net(&pdu.top, &td->o); fio_net_queue_cmd(FIO_NET_CMD_ADD_JOB, &pdu, sizeof(pdu), NULL, SK_F_COPY); } void fio_server_send_start(struct thread_data *td) { struct sk_out *sk_out = pthread_getspecific(sk_out_key); assert(sk_out->sk != -1); fio_net_queue_cmd(FIO_NET_CMD_SERVER_START, NULL, 0, NULL, SK_F_SIMPLE); } int fio_server_get_verify_state(const char *name, int threadnumber, void **datap) { struct thread_io_list *s; struct cmd_sendfile out; struct cmd_reply *rep; uint64_t tag; void *data; int ret; dprint(FD_NET, "server: request verify state\n"); rep = smalloc(sizeof(*rep)); if (!rep) return ENOMEM; __fio_mutex_init(&rep->lock, FIO_MUTEX_LOCKED); rep->data = NULL; rep->error = 0; verify_state_gen_name((char *) out.path, sizeof(out.path), name, me, threadnumber); tag = (uint64_t) (uintptr_t) rep; fio_net_queue_cmd(FIO_NET_CMD_SENDFILE, &out, sizeof(out), &tag, SK_F_COPY); /* * Wait for the backend to receive the reply */ if (fio_mutex_down_timeout(&rep->lock, 10000)) { log_err("fio: timed out waiting for reply\n"); ret = ETIMEDOUT; goto fail; } if (rep->error) { log_err("fio: failure on receiving state file %s: %s\n", out.path, strerror(rep->error)); ret = rep->error; fail: *datap = NULL; sfree(rep); fio_net_queue_quit(); return ret; } /* * The format is verify_state_hdr, then thread_io_list. Verify * the header, and the thread_io_list checksum */ s = rep->data + sizeof(struct verify_state_hdr); if (verify_state_hdr(rep->data, s)) { ret = EILSEQ; goto fail; } /* * Don't need the header from now, copy just the thread_io_list */ ret = 0; rep->size -= sizeof(struct verify_state_hdr); data = malloc(rep->size); memcpy(data, s, rep->size); *datap = data; sfree(rep->data); __fio_mutex_remove(&rep->lock); sfree(rep); return ret; } static int fio_init_server_ip(void) { struct sockaddr *addr; socklen_t socklen; char buf[80]; const char *str; int sk, opt; if (use_ipv6) sk = socket(AF_INET6, SOCK_STREAM, 0); else sk = socket(AF_INET, SOCK_STREAM, 0); if (sk < 0) { log_err("fio: socket: %s\n", strerror(errno)); return -1; } opt = 1; if (setsockopt(sk, SOL_SOCKET, SO_REUSEADDR, (void *)&opt, sizeof(opt)) < 0) { log_err("fio: setsockopt(REUSEADDR): %s\n", strerror(errno)); close(sk); return -1; } #ifdef SO_REUSEPORT /* * Not fatal if fails, so just ignore it if that happens */ setsockopt(sk, SOL_SOCKET, SO_REUSEPORT, &opt, sizeof(opt)); #endif if (use_ipv6) { const void *src = &saddr_in6.sin6_addr; addr = (struct sockaddr *) &saddr_in6; socklen = sizeof(saddr_in6); saddr_in6.sin6_family = AF_INET6; str = inet_ntop(AF_INET6, src, buf, sizeof(buf)); } else { const void *src = &saddr_in.sin_addr; addr = (struct sockaddr *) &saddr_in; socklen = sizeof(saddr_in); saddr_in.sin_family = AF_INET; str = inet_ntop(AF_INET, src, buf, sizeof(buf)); } if (bind(sk, addr, socklen) < 0) { log_err("fio: bind: %s\n", strerror(errno)); log_info("fio: failed with IPv%c %s\n", use_ipv6 ? '6' : '4', str); close(sk); return -1; } return sk; } static int fio_init_server_sock(void) { struct sockaddr_un addr; socklen_t len; mode_t mode; int sk; sk = socket(AF_UNIX, SOCK_STREAM, 0); if (sk < 0) { log_err("fio: socket: %s\n", strerror(errno)); return -1; } mode = umask(000); memset(&addr, 0, sizeof(addr)); addr.sun_family = AF_UNIX; strncpy(addr.sun_path, bind_sock, sizeof(addr.sun_path) - 1); len = sizeof(addr.sun_family) + strlen(bind_sock) + 1; if (bind(sk, (struct sockaddr *) &addr, len) < 0) { log_err("fio: bind: %s\n", strerror(errno)); close(sk); return -1; } umask(mode); return sk; } static int fio_init_server_connection(void) { char bind_str[128]; int sk; dprint(FD_NET, "starting server\n"); if (!bind_sock) sk = fio_init_server_ip(); else sk = fio_init_server_sock(); if (sk < 0) return sk; memset(bind_str, 0, sizeof(bind_str)); if (!bind_sock) { char *p, port[16]; const void *src; int af; if (use_ipv6) { af = AF_INET6; src = &saddr_in6.sin6_addr; } else { af = AF_INET; src = &saddr_in.sin_addr; } p = (char *) inet_ntop(af, src, bind_str, sizeof(bind_str)); sprintf(port, ",%u", fio_net_port); if (p) strcat(p, port); else strncpy(bind_str, port, sizeof(bind_str) - 1); } else strncpy(bind_str, bind_sock, sizeof(bind_str) - 1); log_info("fio: server listening on %s\n", bind_str); if (listen(sk, 4) < 0) { log_err("fio: listen: %s\n", strerror(errno)); close(sk); return -1; } return sk; } int fio_server_parse_host(const char *host, int ipv6, struct in_addr *inp, struct in6_addr *inp6) { int ret = 0; if (ipv6) ret = inet_pton(AF_INET6, host, inp6); else ret = inet_pton(AF_INET, host, inp); if (ret != 1) { struct addrinfo hints, *res; memset(&hints, 0, sizeof(hints)); hints.ai_family = ipv6 ? AF_INET6 : AF_INET; hints.ai_socktype = SOCK_STREAM; ret = getaddrinfo(host, NULL, &hints, &res); if (ret) { log_err("fio: failed to resolve <%s> (%s)\n", host, gai_strerror(ret)); return 1; } if (ipv6) memcpy(inp6, &((struct sockaddr_in6 *) res->ai_addr)->sin6_addr, sizeof(*inp6)); else memcpy(inp, &((struct sockaddr_in *) res->ai_addr)->sin_addr, sizeof(*inp)); ret = 1; freeaddrinfo(res); } return !(ret == 1); } /* * Parse a host/ip/port string. Reads from 'str'. * * Outputs: * * For IPv4: * *ptr is the host, *port is the port, inp is the destination. * For IPv6: * *ptr is the host, *port is the port, inp6 is the dest, and *ipv6 is 1. * For local domain sockets: * *ptr is the filename, *is_sock is 1. */ int fio_server_parse_string(const char *str, char **ptr, int *is_sock, int *port, struct in_addr *inp, struct in6_addr *inp6, int *ipv6) { const char *host = str; char *portp; int lport = 0; *ptr = NULL; *is_sock = 0; *port = fio_net_port; *ipv6 = 0; if (!strncmp(str, "sock:", 5)) { *ptr = strdup(str + 5); *is_sock = 1; return 0; } /* * Is it ip:<ip or host>:port */ if (!strncmp(host, "ip:", 3)) host += 3; else if (!strncmp(host, "ip4:", 4)) host += 4; else if (!strncmp(host, "ip6:", 4)) { host += 4; *ipv6 = 1; } else if (host[0] == ':') { /* String is :port */ host++; lport = atoi(host); if (!lport || lport > 65535) { log_err("fio: bad server port %u\n", lport); return 1; } /* no hostname given, we are done */ *port = lport; return 0; } /* * If no port seen yet, check if there's a last ',' at the end */ if (!lport) { portp = strchr(host, ','); if (portp) { *portp = '\0'; portp++; lport = atoi(portp); if (!lport || lport > 65535) { log_err("fio: bad server port %u\n", lport); return 1; } } } if (lport) *port = lport; if (!strlen(host)) return 0; *ptr = strdup(host); if (fio_server_parse_host(*ptr, *ipv6, inp, inp6)) { free(*ptr); *ptr = NULL; return 1; } if (*port == 0) *port = fio_net_port; return 0; } /* * Server arg should be one of: * * sock:/path/to/socket * ip:1.2.3.4 * 1.2.3.4 * * Where sock uses unix domain sockets, and ip binds the server to * a specific interface. If no arguments are given to the server, it * uses IP and binds to 0.0.0.0. * */ static int fio_handle_server_arg(void) { int port = fio_net_port; int is_sock, ret = 0; saddr_in.sin_addr.s_addr = htonl(INADDR_ANY); if (!fio_server_arg) goto out; ret = fio_server_parse_string(fio_server_arg, &bind_sock, &is_sock, &port, &saddr_in.sin_addr, &saddr_in6.sin6_addr, &use_ipv6); if (!is_sock && bind_sock) { free(bind_sock); bind_sock = NULL; } out: fio_net_port = port; saddr_in.sin_port = htons(port); saddr_in6.sin6_port = htons(port); return ret; } static void sig_int(int sig) { if (bind_sock) unlink(bind_sock); } static void set_sig_handlers(void) { struct sigaction act; memset(&act, 0, sizeof(act)); act.sa_handler = sig_int; act.sa_flags = SA_RESTART; sigaction(SIGINT, &act, NULL); } void fio_server_destroy_sk_key(void) { pthread_key_delete(sk_out_key); } int fio_server_create_sk_key(void) { if (pthread_key_create(&sk_out_key, NULL)) { log_err("fio: can't create sk_out backend key\n"); return 1; } pthread_setspecific(sk_out_key, NULL); return 0; } static int fio_server(void) { int sk, ret; dprint(FD_NET, "starting server\n"); if (fio_handle_server_arg()) return -1; sk = fio_init_server_connection(); if (sk < 0) return -1; set_sig_handlers(); ret = accept_loop(sk); close(sk); if (fio_server_arg) { free(fio_server_arg); fio_server_arg = NULL; } if (bind_sock) free(bind_sock); return ret; } void fio_server_got_signal(int signal) { struct sk_out *sk_out = pthread_getspecific(sk_out_key); assert(sk_out); if (signal == SIGPIPE) sk_out->sk = -1; else { log_info("\nfio: terminating on signal %d\n", signal); exit_backend = 1; } } static int check_existing_pidfile(const char *pidfile) { struct stat sb; char buf[16]; pid_t pid; FILE *f; if (stat(pidfile, &sb)) return 0; f = fopen(pidfile, "r"); if (!f) return 0; if (fread(buf, sb.st_size, 1, f) <= 0) { fclose(f); return 1; } fclose(f); pid = atoi(buf); if (kill(pid, SIGCONT) < 0) return errno != ESRCH; return 1; } static int write_pid(pid_t pid, const char *pidfile) { FILE *fpid; fpid = fopen(pidfile, "w"); if (!fpid) { log_err("fio: failed opening pid file %s\n", pidfile); return 1; } fprintf(fpid, "%u\n", (unsigned int) pid); fclose(fpid); return 0; } /* * If pidfile is specified, background us. */ int fio_start_server(char *pidfile) { pid_t pid; int ret; #if defined(WIN32) WSADATA wsd; WSAStartup(MAKEWORD(2, 2), &wsd); #endif if (!pidfile) return fio_server(); if (check_existing_pidfile(pidfile)) { log_err("fio: pidfile %s exists and server appears alive\n", pidfile); free(pidfile); return -1; } pid = fork(); if (pid < 0) { log_err("fio: failed server fork: %s\n", strerror(errno)); free(pidfile); return -1; } else if (pid) { ret = write_pid(pid, pidfile); free(pidfile); _exit(ret); } setsid(); openlog("fio", LOG_NDELAY|LOG_NOWAIT|LOG_PID, LOG_USER); log_syslog = 1; close(STDIN_FILENO); close(STDOUT_FILENO); close(STDERR_FILENO); f_out = NULL; f_err = NULL; ret = fio_server(); closelog(); unlink(pidfile); free(pidfile); return ret; } void fio_server_set_arg(const char *arg) { fio_server_arg = strdup(arg); }