/* * GPL HEADER START * * DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER. * * This program is free software; you can redistribute it and/or modify * it under the terms of the GNU General Public License version 2 only, * as published by the Free Software Foundation. * * 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 version 2 for more details (a copy is included * in the LICENSE file that accompanied this code). * * You should have received a copy of the GNU General Public License * version 2 along with this program; If not, see * http://www.gnu.org/licenses/gpl-2.0.html * * GPL HEADER END */ /* * Copyright (c) 2008, 2010, Oracle and/or its affiliates. All rights reserved. * Use is subject to license terms. * * Copyright (c) 2012, 2017, Intel Corporation. */ /* * This file is part of Lustre, http://www.lustre.org/ * Lustre is a trademark of Sun Microsystems, Inc. * * libcfs/libcfs/tracefile.c * * Author: Zach Brown * Author: Phil Schwan */ #define DEBUG_SUBSYSTEM S_LNET #define LUSTRE_TRACEFILE_PRIVATE #include "tracefile.h" #include #include #include #include #include #include #include #include #include /* XXX move things up to the top, comment */ union cfs_trace_data_union (*cfs_trace_data[TCD_MAX_TYPES])[NR_CPUS] __cacheline_aligned; char *cfs_trace_console_buffers[NR_CPUS][CFS_TCD_TYPE_MAX]; char cfs_tracefile[TRACEFILE_NAME_SIZE]; long long cfs_tracefile_size = CFS_TRACEFILE_SIZE; static struct tracefiled_ctl trace_tctl; static DEFINE_MUTEX(cfs_trace_thread_mutex); static int thread_running = 0; static atomic_t cfs_tage_allocated = ATOMIC_INIT(0); static DECLARE_RWSEM(cfs_tracefile_sem); static void put_pages_on_tcd_daemon_list(struct page_collection *pc, struct cfs_trace_cpu_data *tcd); /* trace file lock routines */ /* The walking argument indicates the locking comes from all tcd types * iterator and we must lock it and dissable local irqs to avoid deadlocks * with other interrupt locks that might be happening. See LU-1311 * for details. */ int cfs_trace_lock_tcd(struct cfs_trace_cpu_data *tcd, int walking) __acquires(&tcd->tcd_lock) { __LASSERT(tcd->tcd_type < CFS_TCD_TYPE_MAX); if (tcd->tcd_type == CFS_TCD_TYPE_IRQ) spin_lock_irqsave(&tcd->tcd_lock, tcd->tcd_lock_flags); else if (tcd->tcd_type == CFS_TCD_TYPE_SOFTIRQ) spin_lock_bh(&tcd->tcd_lock); else if (unlikely(walking)) spin_lock_irq(&tcd->tcd_lock); else spin_lock(&tcd->tcd_lock); return 1; } void cfs_trace_unlock_tcd(struct cfs_trace_cpu_data *tcd, int walking) __releases(&tcd->tcd_lock) { __LASSERT(tcd->tcd_type < CFS_TCD_TYPE_MAX); if (tcd->tcd_type == CFS_TCD_TYPE_IRQ) spin_unlock_irqrestore(&tcd->tcd_lock, tcd->tcd_lock_flags); else if (tcd->tcd_type == CFS_TCD_TYPE_SOFTIRQ) spin_unlock_bh(&tcd->tcd_lock); else if (unlikely(walking)) spin_unlock_irq(&tcd->tcd_lock); else spin_unlock(&tcd->tcd_lock); } #define cfs_tcd_for_each_type_lock(tcd, i, cpu) \ for (i = 0; cfs_trace_data[i] && \ (tcd = &(*cfs_trace_data[i])[cpu].tcd) && \ cfs_trace_lock_tcd(tcd, 1); cfs_trace_unlock_tcd(tcd, 1), i++) enum cfs_trace_buf_type cfs_trace_buf_idx_get(void) { if (in_irq()) return CFS_TCD_TYPE_IRQ; if (in_softirq()) return CFS_TCD_TYPE_SOFTIRQ; return CFS_TCD_TYPE_PROC; } static inline struct cfs_trace_cpu_data * cfs_trace_get_tcd(void) { struct cfs_trace_cpu_data *tcd = &(*cfs_trace_data[cfs_trace_buf_idx_get()])[get_cpu()].tcd; cfs_trace_lock_tcd(tcd, 0); return tcd; } static inline void cfs_trace_put_tcd(struct cfs_trace_cpu_data *tcd) { cfs_trace_unlock_tcd(tcd, 0); put_cpu(); } /* percents to share the total debug memory for each type */ static unsigned int pages_factor[CFS_TCD_TYPE_MAX] = { 80, /* 80% pages for CFS_TCD_TYPE_PROC */ 10, /* 10% pages for CFS_TCD_TYPE_SOFTIRQ */ 10 /* 10% pages for CFS_TCD_TYPE_IRQ */ }; int cfs_tracefile_init_arch(void) { struct cfs_trace_cpu_data *tcd; int i; int j; /* initialize trace_data */ memset(cfs_trace_data, 0, sizeof(cfs_trace_data)); for (i = 0; i < CFS_TCD_TYPE_MAX; i++) { cfs_trace_data[i] = kmalloc_array(num_possible_cpus(), sizeof(union cfs_trace_data_union), GFP_KERNEL); if (!cfs_trace_data[i]) goto out_trace_data; } /* arch related info initialized */ cfs_tcd_for_each(tcd, i, j) { spin_lock_init(&tcd->tcd_lock); tcd->tcd_pages_factor = pages_factor[i]; tcd->tcd_type = i; tcd->tcd_cpu = j; } for (i = 0; i < num_possible_cpus(); i++) for (j = 0; j < 3; j++) { cfs_trace_console_buffers[i][j] = kmalloc(CFS_TRACE_CONSOLE_BUFFER_SIZE, GFP_KERNEL); if (!cfs_trace_console_buffers[i][j]) goto out_buffers; } return 0; out_buffers: for (i = 0; i < num_possible_cpus(); i++) for (j = 0; j < 3; j++) { kfree(cfs_trace_console_buffers[i][j]); cfs_trace_console_buffers[i][j] = NULL; } out_trace_data: for (i = 0; cfs_trace_data[i]; i++) { kfree(cfs_trace_data[i]); cfs_trace_data[i] = NULL; } pr_err("lnet: Not enough memory\n"); return -ENOMEM; } void cfs_tracefile_fini_arch(void) { int i; int j; for (i = 0; i < num_possible_cpus(); i++) for (j = 0; j < 3; j++) { kfree(cfs_trace_console_buffers[i][j]); cfs_trace_console_buffers[i][j] = NULL; } for (i = 0; cfs_trace_data[i]; i++) { kfree(cfs_trace_data[i]); cfs_trace_data[i] = NULL; } } static inline struct cfs_trace_page * cfs_tage_from_list(struct list_head *list) { return list_entry(list, struct cfs_trace_page, linkage); } static struct cfs_trace_page *cfs_tage_alloc(gfp_t gfp) { struct page *page; struct cfs_trace_page *tage; /* My caller is trying to free memory */ if (!in_interrupt() && (current->flags & PF_MEMALLOC)) return NULL; /* * Don't spam console with allocation failures: they will be reported * by upper layer anyway. */ gfp |= __GFP_NOWARN; page = alloc_page(gfp); if (page == NULL) return NULL; tage = kmalloc(sizeof(*tage), gfp); if (tage == NULL) { __free_page(page); return NULL; } tage->page = page; atomic_inc(&cfs_tage_allocated); return tage; } static void cfs_tage_free(struct cfs_trace_page *tage) { __LASSERT(tage != NULL); __LASSERT(tage->page != NULL); __free_page(tage->page); kfree(tage); atomic_dec(&cfs_tage_allocated); } static void cfs_tage_to_tail(struct cfs_trace_page *tage, struct list_head *queue) { __LASSERT(tage != NULL); __LASSERT(queue != NULL); list_move_tail(&tage->linkage, queue); } /* return a page that has 'len' bytes left at the end */ static struct cfs_trace_page * cfs_trace_get_tage_try(struct cfs_trace_cpu_data *tcd, unsigned long len) { struct cfs_trace_page *tage; if (tcd->tcd_cur_pages > 0) { __LASSERT(!list_empty(&tcd->tcd_pages)); tage = cfs_tage_from_list(tcd->tcd_pages.prev); if (tage->used + len <= PAGE_SIZE) return tage; } if (tcd->tcd_cur_pages < tcd->tcd_max_pages) { if (tcd->tcd_cur_stock_pages > 0) { tage = cfs_tage_from_list(tcd->tcd_stock_pages.prev); --tcd->tcd_cur_stock_pages; list_del_init(&tage->linkage); } else { tage = cfs_tage_alloc(GFP_ATOMIC); if (unlikely(tage == NULL)) { if ((!(current->flags & PF_MEMALLOC) || in_interrupt()) && printk_ratelimit()) pr_warn("Lustre: cannot allocate a tage (%ld)\n", tcd->tcd_cur_pages); return NULL; } } tage->used = 0; tage->cpu = smp_processor_id(); tage->type = tcd->tcd_type; list_add_tail(&tage->linkage, &tcd->tcd_pages); tcd->tcd_cur_pages++; if (tcd->tcd_cur_pages > 8 && thread_running) { struct tracefiled_ctl *tctl = &trace_tctl; /* * wake up tracefiled to process some pages. */ wake_up(&tctl->tctl_waitq); } return tage; } return NULL; } static void cfs_tcd_shrink(struct cfs_trace_cpu_data *tcd) { int pgcount = tcd->tcd_cur_pages / 10; struct page_collection pc; struct cfs_trace_page *tage; struct cfs_trace_page *tmp; /* * XXX nikita: do NOT call portals_debug_msg() (CDEBUG/ENTRY/EXIT) * from here: this will lead to infinite recursion. */ if (printk_ratelimit()) pr_warn("Lustre: debug daemon buffer overflowed; discarding 10%% of pages (%d of %ld)\n", pgcount + 1, tcd->tcd_cur_pages); INIT_LIST_HEAD(&pc.pc_pages); list_for_each_entry_safe(tage, tmp, &tcd->tcd_pages, linkage) { if (pgcount-- == 0) break; list_move_tail(&tage->linkage, &pc.pc_pages); tcd->tcd_cur_pages--; } put_pages_on_tcd_daemon_list(&pc, tcd); } /* return a page that has 'len' bytes left at the end */ static struct cfs_trace_page *cfs_trace_get_tage(struct cfs_trace_cpu_data *tcd, unsigned long len) { struct cfs_trace_page *tage; /* * XXX nikita: do NOT call portals_debug_msg() (CDEBUG/ENTRY/EXIT) * from here: this will lead to infinite recursion. */ if (len > PAGE_SIZE) { pr_err("LustreError: cowardly refusing to write %lu bytes in a page\n", len); return NULL; } tage = cfs_trace_get_tage_try(tcd, len); if (tage != NULL) return tage; if (thread_running) cfs_tcd_shrink(tcd); if (tcd->tcd_cur_pages > 0) { tage = cfs_tage_from_list(tcd->tcd_pages.next); tage->used = 0; cfs_tage_to_tail(tage, &tcd->tcd_pages); } return tage; } static void cfs_set_ptldebug_header(struct ptldebug_header *header, struct libcfs_debug_msg_data *msgdata, unsigned long stack) { struct timespec64 ts; ktime_get_real_ts64(&ts); header->ph_subsys = msgdata->msg_subsys; header->ph_mask = msgdata->msg_mask; header->ph_cpu_id = smp_processor_id(); header->ph_type = cfs_trace_buf_idx_get(); /* y2038 safe since all user space treats this as unsigned, but * will overflow in 2106 */ header->ph_sec = (u32)ts.tv_sec; header->ph_usec = ts.tv_nsec / NSEC_PER_USEC; header->ph_stack = stack; header->ph_pid = current->pid; header->ph_line_num = msgdata->msg_line; header->ph_extern_pid = 0; } /** * tty_write_msg - write a message to a certain tty, not just the console. * @tty: the destination tty_struct * @msg: the message to write * * tty_write_message is not exported, so write a same function for it * */ static void tty_write_msg(struct tty_struct *tty, const char *msg) { mutex_lock(&tty->atomic_write_lock); tty_lock(tty); if (tty->ops->write && tty->count > 0) tty->ops->write(tty, msg, strlen(msg)); tty_unlock(tty); mutex_unlock(&tty->atomic_write_lock); wake_up_interruptible_poll(&tty->write_wait, POLLOUT); } static void cfs_tty_write_message(const char *prefix, int mask, const char *msg) { struct tty_struct *tty; tty = get_current_tty(); if (!tty) return; tty_write_msg(tty, prefix); if ((mask & D_EMERG) || (mask & D_ERROR)) tty_write_msg(tty, "Error"); tty_write_msg(tty, ": "); tty_write_msg(tty, msg); tty_kref_put(tty); } static void cfs_print_to_console(struct ptldebug_header *hdr, int mask, const char *buf, int len, const char *file, const char *fn) { char *prefix = "Lustre"; if (hdr->ph_subsys == S_LND || hdr->ph_subsys == S_LNET) prefix = "LNet"; if (mask & D_CONSOLE) { if (mask & D_EMERG) pr_emerg("%sError: %.*s", prefix, len, buf); else if (mask & D_ERROR) pr_err("%sError: %.*s", prefix, len, buf); else if (mask & D_WARNING) pr_warn("%s: %.*s", prefix, len, buf); else if (mask & libcfs_printk) pr_info("%s: %.*s", prefix, len, buf); } else { if (mask & D_EMERG) pr_emerg("%sError: %d:%d:(%s:%d:%s()) %.*s", prefix, hdr->ph_pid, hdr->ph_extern_pid, file, hdr->ph_line_num, fn, len, buf); else if (mask & D_ERROR) pr_err("%sError: %d:%d:(%s:%d:%s()) %.*s", prefix, hdr->ph_pid, hdr->ph_extern_pid, file, hdr->ph_line_num, fn, len, buf); else if (mask & D_WARNING) pr_warn("%s: %d:%d:(%s:%d:%s()) %.*s", prefix, hdr->ph_pid, hdr->ph_extern_pid, file, hdr->ph_line_num, fn, len, buf); else if (mask & (D_CONSOLE | libcfs_printk)) pr_info("%s: %.*s", prefix, len, buf); } if (mask & D_TTY) cfs_tty_write_message(prefix, mask, buf); } int libcfs_debug_msg(struct libcfs_debug_msg_data *msgdata, const char *format, ...) { struct cfs_trace_cpu_data *tcd = NULL; struct ptldebug_header header = {0}; struct cfs_trace_page *tage; /* string_buf is used only if tcd != NULL, and is always set then */ char *string_buf = NULL; char *debug_buf; int known_size; int needed = 85; /* seeded with average message length */ int max_nob; va_list ap; int retry; int mask = msgdata->msg_mask; char *file = (char *)msgdata->msg_file; struct cfs_debug_limit_state *cdls = msgdata->msg_cdls; if (strchr(file, '/')) file = strrchr(file, '/') + 1; tcd = cfs_trace_get_tcd(); /* cfs_trace_get_tcd() grabs a lock, which disables preemption and * pins us to a particular CPU. This avoids an smp_processor_id() * warning on Linux when debugging is enabled. */ cfs_set_ptldebug_header(&header, msgdata, CDEBUG_STACK()); if (!tcd) /* arch may not log in IRQ context */ goto console; if (tcd->tcd_cur_pages == 0) header.ph_flags |= PH_FLAG_FIRST_RECORD; if (tcd->tcd_shutting_down) { cfs_trace_put_tcd(tcd); tcd = NULL; goto console; } known_size = strlen(file) + 1; if (msgdata->msg_fn) known_size += strlen(msgdata->msg_fn) + 1; if (libcfs_debug_binary) known_size += sizeof(header); /* * May perform an additional pass to update 'needed' and increase * tage buffer size to match vsnprintf reported size required * On the second pass (retry=1) use vscnprintf [which returns * number of bytes written not including the terminating nul] * to clarify `needed` is used as number of bytes written * for the remainder of this function */ for (retry = 0; retry < 2; retry++) { tage = cfs_trace_get_tage(tcd, needed + known_size + 1); if (!tage) { if (needed + known_size > PAGE_SIZE) mask |= D_ERROR; cfs_trace_put_tcd(tcd); tcd = NULL; goto console; } string_buf = (char *)page_address(tage->page) + tage->used + known_size; max_nob = PAGE_SIZE - tage->used - known_size; if (max_nob <= 0) { pr_emerg("LustreError: negative max_nob: %d\n", max_nob); mask |= D_ERROR; cfs_trace_put_tcd(tcd); tcd = NULL; goto console; } va_start(ap, format); if (retry) needed = vscnprintf(string_buf, max_nob, format, ap); else needed = vsnprintf(string_buf, max_nob, format, ap); va_end(ap); if (needed < max_nob) /* well. printing ok.. */ break; } /* `needed` is actual bytes written to string_buf */ if (*(string_buf + needed - 1) != '\n') { pr_info("Lustre: format at %s:%d:%s doesn't end in newline\n", file, msgdata->msg_line, msgdata->msg_fn); } else if (mask & D_TTY) { /* TTY needs '\r\n' to move carriage to leftmost position */ if (needed < 2 || *(string_buf + needed - 2) != '\r') pr_info("Lustre: format at %s:%d:%s doesn't end in '\\r\\n'\n", file, msgdata->msg_line, msgdata->msg_fn); } header.ph_len = known_size + needed; debug_buf = (char *)page_address(tage->page) + tage->used; if (libcfs_debug_binary) { memcpy(debug_buf, &header, sizeof(header)); tage->used += sizeof(header); debug_buf += sizeof(header); } strlcpy(debug_buf, file, PAGE_SIZE - tage->used); tage->used += strlen(file) + 1; debug_buf += strlen(file) + 1; if (msgdata->msg_fn) { strlcpy(debug_buf, msgdata->msg_fn, PAGE_SIZE - tage->used); tage->used += strlen(msgdata->msg_fn) + 1; debug_buf += strlen(msgdata->msg_fn) + 1; } __LASSERT(debug_buf == string_buf); tage->used += needed; __LASSERT(tage->used <= PAGE_SIZE); console: if ((mask & libcfs_printk) == 0) { /* no console output requested */ if (tcd != NULL) cfs_trace_put_tcd(tcd); return 1; } if (cdls != NULL) { if (libcfs_console_ratelimit && cdls->cdls_next != 0 && /* not first time ever */ time_before(jiffies, cdls->cdls_next)) { /* skipping a console message */ cdls->cdls_count++; if (tcd != NULL) cfs_trace_put_tcd(tcd); return 1; } if (time_after(jiffies, cdls->cdls_next + libcfs_console_max_delay + cfs_time_seconds(10))) { /* last timeout was a long time ago */ cdls->cdls_delay /= libcfs_console_backoff * 4; } else { cdls->cdls_delay *= libcfs_console_backoff; } if (cdls->cdls_delay < libcfs_console_min_delay) cdls->cdls_delay = libcfs_console_min_delay; else if (cdls->cdls_delay > libcfs_console_max_delay) cdls->cdls_delay = libcfs_console_max_delay; /* ensure cdls_next is never zero after it's been seen */ cdls->cdls_next = (jiffies + cdls->cdls_delay) | 1; } if (tcd) { cfs_print_to_console(&header, mask, string_buf, needed, file, msgdata->msg_fn); cfs_trace_put_tcd(tcd); } else { string_buf = cfs_trace_get_console_buffer(); va_start(ap, format); needed = vscnprintf(string_buf, CFS_TRACE_CONSOLE_BUFFER_SIZE, format, ap); va_end(ap); cfs_print_to_console(&header, mask, string_buf, needed, file, msgdata->msg_fn); put_cpu(); } if (cdls != NULL && cdls->cdls_count != 0) { string_buf = cfs_trace_get_console_buffer(); needed = scnprintf(string_buf, CFS_TRACE_CONSOLE_BUFFER_SIZE, "Skipped %d previous similar message%s\n", cdls->cdls_count, (cdls->cdls_count > 1) ? "s" : ""); /* Do not allow print this to TTY */ cfs_print_to_console(&header, mask & ~D_TTY, string_buf, needed, file, msgdata->msg_fn); put_cpu(); cdls->cdls_count = 0; } return 0; } EXPORT_SYMBOL(libcfs_debug_msg); void cfs_trace_assertion_failed(const char *str, struct libcfs_debug_msg_data *msgdata) { struct ptldebug_header hdr; libcfs_panic_in_progress = 1; libcfs_catastrophe = 1; smp_mb(); cfs_set_ptldebug_header(&hdr, msgdata, CDEBUG_STACK()); cfs_print_to_console(&hdr, D_EMERG, str, strlen(str), msgdata->msg_file, msgdata->msg_fn); panic("Lustre debug assertion failure\n"); /* not reached */ } static void panic_collect_pages(struct page_collection *pc) { /* Do the collect_pages job on a single CPU: assumes that all other * CPUs have been stopped during a panic. If this isn't true for some * arch, this will have to be implemented separately in each arch. */ int i; int j; struct cfs_trace_cpu_data *tcd; INIT_LIST_HEAD(&pc->pc_pages); cfs_tcd_for_each(tcd, i, j) { list_splice_init(&tcd->tcd_pages, &pc->pc_pages); tcd->tcd_cur_pages = 0; if (pc->pc_want_daemon_pages) { list_splice_init(&tcd->tcd_daemon_pages, &pc->pc_pages); tcd->tcd_cur_daemon_pages = 0; } } } static void collect_pages_on_all_cpus(struct page_collection *pc) { struct cfs_trace_cpu_data *tcd; int i, cpu; for_each_possible_cpu(cpu) { cfs_tcd_for_each_type_lock(tcd, i, cpu) { list_splice_init(&tcd->tcd_pages, &pc->pc_pages); tcd->tcd_cur_pages = 0; if (pc->pc_want_daemon_pages) { list_splice_init(&tcd->tcd_daemon_pages, &pc->pc_pages); tcd->tcd_cur_daemon_pages = 0; } } } } static void collect_pages(struct page_collection *pc) { INIT_LIST_HEAD(&pc->pc_pages); if (libcfs_panic_in_progress) panic_collect_pages(pc); else collect_pages_on_all_cpus(pc); } static void put_pages_back_on_all_cpus(struct page_collection *pc) { struct cfs_trace_cpu_data *tcd; struct list_head *cur_head; struct cfs_trace_page *tage; struct cfs_trace_page *tmp; int i, cpu; for_each_possible_cpu(cpu) { cfs_tcd_for_each_type_lock(tcd, i, cpu) { cur_head = tcd->tcd_pages.next; list_for_each_entry_safe(tage, tmp, &pc->pc_pages, linkage) { __LASSERT_TAGE_INVARIANT(tage); if (tage->cpu != cpu || tage->type != i) continue; cfs_tage_to_tail(tage, cur_head); tcd->tcd_cur_pages++; } } } } static void put_pages_back(struct page_collection *pc) { if (!libcfs_panic_in_progress) put_pages_back_on_all_cpus(pc); } /* Add pages to a per-cpu debug daemon ringbuffer. This buffer makes sure that * we have a good amount of data at all times for dumping during an LBUG, even * if we have been steadily writing (and otherwise discarding) pages via the * debug daemon. */ static void put_pages_on_tcd_daemon_list(struct page_collection *pc, struct cfs_trace_cpu_data *tcd) { struct cfs_trace_page *tage; struct cfs_trace_page *tmp; list_for_each_entry_safe(tage, tmp, &pc->pc_pages, linkage) { __LASSERT_TAGE_INVARIANT(tage); if (tage->cpu != tcd->tcd_cpu || tage->type != tcd->tcd_type) continue; cfs_tage_to_tail(tage, &tcd->tcd_daemon_pages); tcd->tcd_cur_daemon_pages++; if (tcd->tcd_cur_daemon_pages > tcd->tcd_max_pages) { struct cfs_trace_page *victim; __LASSERT(!list_empty(&tcd->tcd_daemon_pages)); victim = cfs_tage_from_list(tcd->tcd_daemon_pages.next); __LASSERT_TAGE_INVARIANT(victim); list_del(&victim->linkage); cfs_tage_free(victim); tcd->tcd_cur_daemon_pages--; } } } static void put_pages_on_daemon_list(struct page_collection *pc) { struct cfs_trace_cpu_data *tcd; int i, cpu; for_each_possible_cpu(cpu) { cfs_tcd_for_each_type_lock(tcd, i, cpu) put_pages_on_tcd_daemon_list(pc, tcd); } } void cfs_trace_debug_print(void) { struct page_collection pc; struct cfs_trace_page *tage; struct cfs_trace_page *tmp; pc.pc_want_daemon_pages = 1; collect_pages(&pc); list_for_each_entry_safe(tage, tmp, &pc.pc_pages, linkage) { char *p, *file, *fn; struct page *page; __LASSERT_TAGE_INVARIANT(tage); page = tage->page; p = page_address(page); while (p < ((char *)page_address(page) + tage->used)) { struct ptldebug_header *hdr; int len; hdr = (void *)p; p += sizeof(*hdr); file = p; p += strlen(file) + 1; fn = p; p += strlen(fn) + 1; len = hdr->ph_len - (int)(p - (char *)hdr); cfs_print_to_console(hdr, D_EMERG, p, len, file, fn); p += len; } list_del(&tage->linkage); cfs_tage_free(tage); } } int cfs_tracefile_dump_all_pages(char *filename) { struct page_collection pc; struct file *filp; struct cfs_trace_page *tage; struct cfs_trace_page *tmp; char *buf; int rc; down_write(&cfs_tracefile_sem); filp = filp_open(filename, O_CREAT|O_EXCL|O_WRONLY|O_LARGEFILE, 0600); if (IS_ERR(filp)) { rc = PTR_ERR(filp); filp = NULL; pr_err("LustreError: can't open %s for dump: rc = %d\n", filename, rc); goto out; } pc.pc_want_daemon_pages = 1; collect_pages(&pc); if (list_empty(&pc.pc_pages)) { rc = 0; goto close; } /* ok, for now, just write the pages. in the future we'll be building * iobufs with the pages and calling generic_direct_IO */ list_for_each_entry_safe(tage, tmp, &pc.pc_pages, linkage) { __LASSERT_TAGE_INVARIANT(tage); buf = kmap(tage->page); rc = cfs_kernel_write(filp, buf, tage->used, &filp->f_pos); kunmap(tage->page); if (rc != (int)tage->used) { pr_warn("Lustre: wanted to write %u but wrote %d\n", tage->used, rc); put_pages_back(&pc); __LASSERT(list_empty(&pc.pc_pages)); break; } list_del(&tage->linkage); cfs_tage_free(tage); } rc = vfs_fsync_range(filp, 0, LLONG_MAX, 1); if (rc) pr_err("LustreError: sync returns: rc = %d\n", rc); close: filp_close(filp, NULL); out: up_write(&cfs_tracefile_sem); return rc; } void cfs_trace_flush_pages(void) { struct page_collection pc; struct cfs_trace_page *tage; struct cfs_trace_page *tmp; pc.pc_want_daemon_pages = 1; collect_pages(&pc); list_for_each_entry_safe(tage, tmp, &pc.pc_pages, linkage) { __LASSERT_TAGE_INVARIANT(tage); list_del(&tage->linkage); cfs_tage_free(tage); } } int cfs_trace_copyin_string(char *knl_buffer, int knl_buffer_nob, const char __user *usr_buffer, int usr_buffer_nob) { int nob; if (usr_buffer_nob > knl_buffer_nob) return -EOVERFLOW; if (copy_from_user(knl_buffer, usr_buffer, usr_buffer_nob)) return -EFAULT; nob = strnlen(knl_buffer, usr_buffer_nob); while (--nob >= 0) /* strip trailing whitespace */ if (!isspace(knl_buffer[nob])) break; if (nob < 0) /* empty string */ return -EINVAL; if (nob == knl_buffer_nob) /* no space to terminate */ return -EOVERFLOW; knl_buffer[nob + 1] = 0; /* terminate */ return 0; } EXPORT_SYMBOL(cfs_trace_copyin_string); int cfs_trace_copyout_string(char __user *usr_buffer, int usr_buffer_nob, const char *knl_buffer, char *append) { /* NB if 'append' != NULL, it's a single character to append to the * copied out string - usually "\n", for /proc entries and "" (i.e. a * terminating zero byte) for sysctl entries */ int nob = strlen(knl_buffer); if (nob > usr_buffer_nob) nob = usr_buffer_nob; if (copy_to_user(usr_buffer, knl_buffer, nob)) return -EFAULT; if (append != NULL && nob < usr_buffer_nob) { if (copy_to_user(usr_buffer + nob, append, 1)) return -EFAULT; nob++; } return nob; } EXPORT_SYMBOL(cfs_trace_copyout_string); int cfs_trace_allocate_string_buffer(char **str, int nob) { if (nob > 2 * PAGE_SIZE) /* string must be "sensible" */ return -EINVAL; *str = kmalloc(nob, GFP_KERNEL | __GFP_ZERO); if (*str == NULL) return -ENOMEM; return 0; } int cfs_trace_dump_debug_buffer_usrstr(void __user *usr_str, int usr_str_nob) { char *str; int rc; rc = cfs_trace_allocate_string_buffer(&str, usr_str_nob + 1); if (rc != 0) return rc; rc = cfs_trace_copyin_string(str, usr_str_nob + 1, usr_str, usr_str_nob); if (rc != 0) goto out; if (str[0] != '/') { rc = -EINVAL; goto out; } rc = cfs_tracefile_dump_all_pages(str); out: kfree(str); return rc; } int cfs_trace_daemon_command(char *str) { int rc = 0; down_write(&cfs_tracefile_sem); if (strcmp(str, "stop") == 0) { up_write(&cfs_tracefile_sem); cfs_trace_stop_thread(); down_write(&cfs_tracefile_sem); memset(cfs_tracefile, 0, sizeof(cfs_tracefile)); } else if (strncmp(str, "size=", 5) == 0) { unsigned long tmp; rc = kstrtoul(str + 5, 10, &tmp); if (!rc) { if (tmp < 10 || tmp > 20480) cfs_tracefile_size = CFS_TRACEFILE_SIZE; else cfs_tracefile_size = tmp << 20; } } else if (strlen(str) >= sizeof(cfs_tracefile)) { rc = -ENAMETOOLONG; } else if (str[0] != '/') { rc = -EINVAL; } else { strcpy(cfs_tracefile, str); pr_info("Lustre: debug daemon will attempt to start writing to %s (%lukB max)\n", cfs_tracefile, (long)(cfs_tracefile_size >> 10)); cfs_trace_start_thread(); } up_write(&cfs_tracefile_sem); return rc; } int cfs_trace_daemon_command_usrstr(void __user *usr_str, int usr_str_nob) { char *str; int rc; rc = cfs_trace_allocate_string_buffer(&str, usr_str_nob + 1); if (rc != 0) return rc; rc = cfs_trace_copyin_string(str, usr_str_nob + 1, usr_str, usr_str_nob); if (rc == 0) rc = cfs_trace_daemon_command(str); kfree(str); return rc; } int cfs_trace_set_debug_mb(int mb) { int i; int j; unsigned long pages; unsigned long total_mb = (cfs_totalram_pages() >> (20 - PAGE_SHIFT)); unsigned long limit = max_t(unsigned long, 512, (total_mb * 4) / 5); struct cfs_trace_cpu_data *tcd; if (mb < num_possible_cpus()) { pr_warn("Lustre: %d MB is too small for debug buffer size, setting it to %d MB.\n", mb, num_possible_cpus()); mb = num_possible_cpus(); } if (mb > limit) { pr_warn("Lustre: %d MB is too large for debug buffer size, setting it to %lu MB.\n", mb, limit); mb = limit; } mb /= num_possible_cpus(); pages = mb << (20 - PAGE_SHIFT); down_write(&cfs_tracefile_sem); cfs_tcd_for_each(tcd, i, j) tcd->tcd_max_pages = (pages * tcd->tcd_pages_factor) / 100; up_write(&cfs_tracefile_sem); return mb; } int cfs_trace_get_debug_mb(void) { int i; int j; struct cfs_trace_cpu_data *tcd; int total_pages = 0; down_read(&cfs_tracefile_sem); cfs_tcd_for_each(tcd, i, j) total_pages += tcd->tcd_max_pages; up_read(&cfs_tracefile_sem); return (total_pages >> (20 - PAGE_SHIFT)) + 1; } static int tracefiled(void *arg) { struct page_collection pc; struct tracefiled_ctl *tctl = arg; struct cfs_trace_page *tage; struct cfs_trace_page *tmp; struct file *filp; char *buf; int last_loop = 0; int rc; /* we're started late enough that we pick up init's fs context */ /* this is so broken in uml? what on earth is going on? */ complete(&tctl->tctl_start); while (1) { wait_queue_entry_t __wait; pc.pc_want_daemon_pages = 0; collect_pages(&pc); if (list_empty(&pc.pc_pages)) goto end_loop; filp = NULL; down_read(&cfs_tracefile_sem); if (cfs_tracefile[0] != 0) { filp = filp_open(cfs_tracefile, O_CREAT | O_RDWR | O_LARGEFILE, 0600); if (IS_ERR(filp)) { rc = PTR_ERR(filp); filp = NULL; pr_warn("Lustre: couldn't open %s: rc = %d\n", cfs_tracefile, rc); } } up_read(&cfs_tracefile_sem); if (filp == NULL) { put_pages_on_daemon_list(&pc); __LASSERT(list_empty(&pc.pc_pages)); goto end_loop; } list_for_each_entry_safe(tage, tmp, &pc.pc_pages, linkage) { struct dentry *de = file_dentry(filp); static loff_t f_pos; __LASSERT_TAGE_INVARIANT(tage); if (f_pos >= (off_t)cfs_tracefile_size) f_pos = 0; else if (f_pos > i_size_read(de->d_inode)) f_pos = i_size_read(de->d_inode); buf = kmap(tage->page); rc = cfs_kernel_write(filp, buf, tage->used, &f_pos); kunmap(tage->page); if (rc != (int)tage->used) { pr_warn("Lustre: wanted to write %u but wrote %d\n", tage->used, rc); put_pages_back(&pc); __LASSERT(list_empty(&pc.pc_pages)); break; } } filp_close(filp, NULL); put_pages_on_daemon_list(&pc); if (!list_empty(&pc.pc_pages)) { int i; pr_alert("Lustre: trace pages aren't empty\n"); pr_err("Lustre: total cpus(%d): ", num_possible_cpus()); for (i = 0; i < num_possible_cpus(); i++) if (cpu_online(i)) pr_cont("%d(on) ", i); else pr_cont("%d(off) ", i); pr_cont("\n"); i = 0; list_for_each_entry_safe(tage, tmp, &pc.pc_pages, linkage) pr_err("Lustre: page %d belongs to cpu %d\n", ++i, tage->cpu); pr_err("Lustre: There are %d pages unwritten\n", i); } __LASSERT(list_empty(&pc.pc_pages)); end_loop: if (atomic_read(&tctl->tctl_shutdown)) { if (last_loop == 0) { last_loop = 1; continue; } else { break; } } init_waitqueue_entry(&__wait, current); add_wait_queue(&tctl->tctl_waitq, &__wait); schedule_timeout_interruptible(cfs_time_seconds(1)); remove_wait_queue(&tctl->tctl_waitq, &__wait); } complete(&tctl->tctl_stop); return 0; } int cfs_trace_start_thread(void) { struct tracefiled_ctl *tctl = &trace_tctl; int rc = 0; mutex_lock(&cfs_trace_thread_mutex); if (thread_running) goto out; init_completion(&tctl->tctl_start); init_completion(&tctl->tctl_stop); init_waitqueue_head(&tctl->tctl_waitq); atomic_set(&tctl->tctl_shutdown, 0); if (IS_ERR(kthread_run(tracefiled, tctl, "ktracefiled"))) { rc = -ECHILD; goto out; } wait_for_completion(&tctl->tctl_start); thread_running = 1; out: mutex_unlock(&cfs_trace_thread_mutex); return rc; } void cfs_trace_stop_thread(void) { struct tracefiled_ctl *tctl = &trace_tctl; mutex_lock(&cfs_trace_thread_mutex); if (thread_running) { pr_info("Lustre: shutting down debug daemon thread...\n"); atomic_set(&tctl->tctl_shutdown, 1); wait_for_completion(&tctl->tctl_stop); thread_running = 0; } mutex_unlock(&cfs_trace_thread_mutex); } int cfs_tracefile_init(int max_pages) { struct cfs_trace_cpu_data *tcd; int i; int j; int rc; int factor; rc = cfs_tracefile_init_arch(); if (rc != 0) return rc; cfs_tcd_for_each(tcd, i, j) { /* tcd_pages_factor is initialized int tracefile_init_arch. */ factor = tcd->tcd_pages_factor; INIT_LIST_HEAD(&tcd->tcd_pages); INIT_LIST_HEAD(&tcd->tcd_stock_pages); INIT_LIST_HEAD(&tcd->tcd_daemon_pages); tcd->tcd_cur_pages = 0; tcd->tcd_cur_stock_pages = 0; tcd->tcd_cur_daemon_pages = 0; tcd->tcd_max_pages = (max_pages * factor) / 100; LASSERT(tcd->tcd_max_pages > 0); tcd->tcd_shutting_down = 0; } return 0; } static void trace_cleanup_on_all_cpus(void) { struct cfs_trace_cpu_data *tcd; struct cfs_trace_page *tage; struct cfs_trace_page *tmp; int i, cpu; for_each_possible_cpu(cpu) { cfs_tcd_for_each_type_lock(tcd, i, cpu) { tcd->tcd_shutting_down = 1; list_for_each_entry_safe(tage, tmp, &tcd->tcd_pages, linkage) { __LASSERT_TAGE_INVARIANT(tage); list_del(&tage->linkage); cfs_tage_free(tage); } tcd->tcd_cur_pages = 0; } } } static void cfs_trace_cleanup(void) { struct page_collection pc; INIT_LIST_HEAD(&pc.pc_pages); trace_cleanup_on_all_cpus(); cfs_tracefile_fini_arch(); } void cfs_tracefile_exit(void) { cfs_trace_stop_thread(); cfs_trace_cleanup(); }