/* Copyright (c) 2012-2017, The Linux Foundation. All rights reserved. * * This program is free software; you can redistribute it and/or modify * it under the terms of the GNU General Public License version 2 and * only version 2 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 for more details. * */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "ipc_logging_private.h" #define LOG_PAGE_DATA_SIZE sizeof(((struct ipc_log_page *)0)->data) #define LOG_PAGE_FLAG (1 << 31) static LIST_HEAD(ipc_log_context_list); static DEFINE_RWLOCK(context_list_lock_lha1); static void *get_deserialization_func(struct ipc_log_context *ilctxt, int type); static struct ipc_log_page *get_first_page(struct ipc_log_context *ilctxt) { struct ipc_log_page_header *p_pghdr; struct ipc_log_page *pg = NULL; if (!ilctxt) return NULL; p_pghdr = list_first_entry(&ilctxt->page_list, struct ipc_log_page_header, list); pg = container_of(p_pghdr, struct ipc_log_page, hdr); return pg; } /** * is_nd_read_empty - Returns true if no data is available to read in log * * @ilctxt: logging context * @returns: > 1 if context is empty; 0 if not empty; <0 for failure * * This is for the debugfs read pointer which allows for a non-destructive read. * There may still be data in the log, but it may have already been read. */ static int is_nd_read_empty(struct ipc_log_context *ilctxt) { if (!ilctxt) return -EINVAL; return ((ilctxt->nd_read_page == ilctxt->write_page) && (ilctxt->nd_read_page->hdr.nd_read_offset == ilctxt->write_page->hdr.write_offset)); } /** * is_read_empty - Returns true if no data is available in log * * @ilctxt: logging context * @returns: > 1 if context is empty; 0 if not empty; <0 for failure * * This is for the actual log contents. If it is empty, then there * is no data at all in the log. */ static int is_read_empty(struct ipc_log_context *ilctxt) { if (!ilctxt) return -EINVAL; return ((ilctxt->read_page == ilctxt->write_page) && (ilctxt->read_page->hdr.read_offset == ilctxt->write_page->hdr.write_offset)); } /** * is_nd_read_equal_read - Return true if the non-destructive read is equal to * the destructive read * * @ilctxt: logging context * @returns: true if nd read is equal to read; false otherwise */ static bool is_nd_read_equal_read(struct ipc_log_context *ilctxt) { uint16_t read_offset; uint16_t nd_read_offset; if (ilctxt->nd_read_page == ilctxt->read_page) { read_offset = ilctxt->read_page->hdr.read_offset; nd_read_offset = ilctxt->nd_read_page->hdr.nd_read_offset; if (read_offset == nd_read_offset) return true; } return false; } static struct ipc_log_page *get_next_page(struct ipc_log_context *ilctxt, struct ipc_log_page *cur_pg) { struct ipc_log_page_header *p_pghdr; struct ipc_log_page *pg = NULL; if (!ilctxt || !cur_pg) return NULL; if (ilctxt->last_page == cur_pg) return ilctxt->first_page; p_pghdr = list_first_entry(&cur_pg->hdr.list, struct ipc_log_page_header, list); pg = container_of(p_pghdr, struct ipc_log_page, hdr); return pg; } /** * ipc_log_read - do non-destructive read of the log * * @ilctxt: Logging context * @data: Data pointer to receive the data * @data_size: Number of bytes to read (must be <= bytes available in log) * * This read will update a runtime read pointer, but will not affect the actual * contents of the log which allows for reading the logs continuously while * debugging and if the system crashes, then the full logs can still be * extracted. */ static void ipc_log_read(struct ipc_log_context *ilctxt, void *data, int data_size) { int bytes_to_read; bytes_to_read = MIN(LOG_PAGE_DATA_SIZE - ilctxt->nd_read_page->hdr.nd_read_offset, data_size); memcpy(data, (ilctxt->nd_read_page->data + ilctxt->nd_read_page->hdr.nd_read_offset), bytes_to_read); if (bytes_to_read != data_size) { /* not enough space, wrap read to next page */ ilctxt->nd_read_page->hdr.nd_read_offset = 0; ilctxt->nd_read_page = get_next_page(ilctxt, ilctxt->nd_read_page); BUG_ON(ilctxt->nd_read_page == NULL); memcpy((data + bytes_to_read), (ilctxt->nd_read_page->data + ilctxt->nd_read_page->hdr.nd_read_offset), (data_size - bytes_to_read)); bytes_to_read = (data_size - bytes_to_read); } ilctxt->nd_read_page->hdr.nd_read_offset += bytes_to_read; } /** * ipc_log_drop - do destructive read of the log * * @ilctxt: Logging context * @data: Data pointer to receive the data (or NULL) * @data_size: Number of bytes to read (must be <= bytes available in log) */ static void ipc_log_drop(struct ipc_log_context *ilctxt, void *data, int data_size) { int bytes_to_read; bool push_nd_read; bytes_to_read = MIN(LOG_PAGE_DATA_SIZE - ilctxt->read_page->hdr.read_offset, data_size); if (data) memcpy(data, (ilctxt->read_page->data + ilctxt->read_page->hdr.read_offset), bytes_to_read); if (bytes_to_read != data_size) { /* not enough space, wrap read to next page */ push_nd_read = is_nd_read_equal_read(ilctxt); ilctxt->read_page->hdr.read_offset = 0; if (push_nd_read) { ilctxt->read_page->hdr.nd_read_offset = 0; ilctxt->read_page = get_next_page(ilctxt, ilctxt->read_page); BUG_ON(ilctxt->read_page == NULL); ilctxt->nd_read_page = ilctxt->read_page; } else { ilctxt->read_page = get_next_page(ilctxt, ilctxt->read_page); BUG_ON(ilctxt->read_page == NULL); } if (data) memcpy((data + bytes_to_read), (ilctxt->read_page->data + ilctxt->read_page->hdr.read_offset), (data_size - bytes_to_read)); bytes_to_read = (data_size - bytes_to_read); } /* update non-destructive read pointer if necessary */ push_nd_read = is_nd_read_equal_read(ilctxt); ilctxt->read_page->hdr.read_offset += bytes_to_read; ilctxt->write_avail += data_size; if (push_nd_read) ilctxt->nd_read_page->hdr.nd_read_offset += bytes_to_read; } /** * msg_read - Reads a message. * * If a message is read successfully, then the message context * will be set to: * .hdr message header .size and .type values * .offset beginning of message data * * @ilctxt Logging context * @ectxt Message context * * @returns 0 - no message available; >0 message size; <0 error */ static int msg_read(struct ipc_log_context *ilctxt, struct encode_context *ectxt) { struct tsv_header hdr; if (!ectxt) return -EINVAL; if (is_nd_read_empty(ilctxt)) return 0; ipc_log_read(ilctxt, &hdr, sizeof(hdr)); ectxt->hdr.type = hdr.type; ectxt->hdr.size = hdr.size; ectxt->offset = sizeof(hdr); ipc_log_read(ilctxt, (ectxt->buff + ectxt->offset), (int)hdr.size); return sizeof(hdr) + (int)hdr.size; } /** * msg_drop - Drops a message. * * @ilctxt Logging context */ static void msg_drop(struct ipc_log_context *ilctxt) { struct tsv_header hdr; if (!is_read_empty(ilctxt)) { ipc_log_drop(ilctxt, &hdr, sizeof(hdr)); ipc_log_drop(ilctxt, NULL, (int)hdr.size); } } /* * Commits messages to the FIFO. If the FIFO is full, then enough * messages are dropped to create space for the new message. */ void ipc_log_write(void *ctxt, struct encode_context *ectxt) { struct ipc_log_context *ilctxt = (struct ipc_log_context *)ctxt; int bytes_to_write; unsigned long flags; if (!ilctxt || !ectxt) { pr_err("%s: Invalid ipc_log or encode context\n", __func__); return; } read_lock_irqsave(&context_list_lock_lha1, flags); spin_lock(&ilctxt->context_lock_lhb1); while (ilctxt->write_avail <= ectxt->offset) msg_drop(ilctxt); bytes_to_write = MIN(LOG_PAGE_DATA_SIZE - ilctxt->write_page->hdr.write_offset, ectxt->offset); memcpy((ilctxt->write_page->data + ilctxt->write_page->hdr.write_offset), ectxt->buff, bytes_to_write); if (bytes_to_write != ectxt->offset) { uint64_t t_now = sched_clock(); ilctxt->write_page->hdr.write_offset += bytes_to_write; ilctxt->write_page->hdr.end_time = t_now; ilctxt->write_page = get_next_page(ilctxt, ilctxt->write_page); BUG_ON(ilctxt->write_page == NULL); ilctxt->write_page->hdr.write_offset = 0; ilctxt->write_page->hdr.start_time = t_now; memcpy((ilctxt->write_page->data + ilctxt->write_page->hdr.write_offset), (ectxt->buff + bytes_to_write), (ectxt->offset - bytes_to_write)); bytes_to_write = (ectxt->offset - bytes_to_write); } ilctxt->write_page->hdr.write_offset += bytes_to_write; ilctxt->write_avail -= ectxt->offset; complete(&ilctxt->read_avail); spin_unlock(&ilctxt->context_lock_lhb1); read_unlock_irqrestore(&context_list_lock_lha1, flags); } EXPORT_SYMBOL(ipc_log_write); /* * Starts a new message after which you can add serialized data and * then complete the message by calling msg_encode_end(). */ void msg_encode_start(struct encode_context *ectxt, uint32_t type) { if (!ectxt) { pr_err("%s: Invalid encode context\n", __func__); return; } ectxt->hdr.type = type; ectxt->hdr.size = 0; ectxt->offset = sizeof(ectxt->hdr); } EXPORT_SYMBOL(msg_encode_start); /* * Completes the message */ void msg_encode_end(struct encode_context *ectxt) { if (!ectxt) { pr_err("%s: Invalid encode context\n", __func__); return; } /* finalize data size */ ectxt->hdr.size = ectxt->offset - sizeof(ectxt->hdr); BUG_ON(ectxt->hdr.size > MAX_MSG_SIZE); memcpy(ectxt->buff, &ectxt->hdr, sizeof(ectxt->hdr)); } EXPORT_SYMBOL(msg_encode_end); /* * Helper funtion used to write data to a message context. * * @ectxt context initialized by calling msg_encode_start() * @data data to write * @size number of bytes of data to write */ static inline int tsv_write_data(struct encode_context *ectxt, void *data, uint32_t size) { if (!ectxt) { pr_err("%s: Invalid encode context\n", __func__); return -EINVAL; } if ((ectxt->offset + size) > MAX_MSG_SIZE) { pr_err("%s: No space to encode further\n", __func__); return -EINVAL; } memcpy((void *)(ectxt->buff + ectxt->offset), data, size); ectxt->offset += size; return 0; } /* * Helper function that writes a type to the context. * * @ectxt context initialized by calling msg_encode_start() * @type primitive type * @size size of primitive in bytes */ static inline int tsv_write_header(struct encode_context *ectxt, uint32_t type, uint32_t size) { struct tsv_header hdr; hdr.type = (unsigned char)type; hdr.size = (unsigned char)size; return tsv_write_data(ectxt, &hdr, sizeof(hdr)); } /* * Writes the current timestamp count. * * @ectxt context initialized by calling msg_encode_start() */ int tsv_timestamp_write(struct encode_context *ectxt) { int ret; uint64_t t_now = sched_clock(); ret = tsv_write_header(ectxt, TSV_TYPE_TIMESTAMP, sizeof(t_now)); if (ret) return ret; return tsv_write_data(ectxt, &t_now, sizeof(t_now)); } EXPORT_SYMBOL(tsv_timestamp_write); /* * Writes the current QTimer timestamp count. * * @ectxt context initialized by calling msg_encode_start() */ int tsv_qtimer_write(struct encode_context *ectxt) { int ret; uint64_t t_now = arch_counter_get_cntvct(); ret = tsv_write_header(ectxt, TSV_TYPE_QTIMER, sizeof(t_now)); if (ret) return ret; return tsv_write_data(ectxt, &t_now, sizeof(t_now)); } EXPORT_SYMBOL(tsv_qtimer_write); /* * Writes a data pointer. * * @ectxt context initialized by calling msg_encode_start() * @pointer pointer value to write */ int tsv_pointer_write(struct encode_context *ectxt, void *pointer) { int ret; ret = tsv_write_header(ectxt, TSV_TYPE_POINTER, sizeof(pointer)); if (ret) return ret; return tsv_write_data(ectxt, &pointer, sizeof(pointer)); } EXPORT_SYMBOL(tsv_pointer_write); /* * Writes a 32-bit integer value. * * @ectxt context initialized by calling msg_encode_start() * @n integer to write */ int tsv_int32_write(struct encode_context *ectxt, int32_t n) { int ret; ret = tsv_write_header(ectxt, TSV_TYPE_INT32, sizeof(n)); if (ret) return ret; return tsv_write_data(ectxt, &n, sizeof(n)); } EXPORT_SYMBOL(tsv_int32_write); /* * Writes a byte array. * * @ectxt context initialized by calling msg_write_start() * @data Beginning address of data * @data_size Size of data to be written */ int tsv_byte_array_write(struct encode_context *ectxt, void *data, int data_size) { int ret; ret = tsv_write_header(ectxt, TSV_TYPE_BYTE_ARRAY, data_size); if (ret) return ret; return tsv_write_data(ectxt, data, data_size); } EXPORT_SYMBOL(tsv_byte_array_write); /* * Helper function to log a string * * @ilctxt ipc_log_context created using ipc_log_context_create() * @fmt Data specified using format specifiers */ int ipc_log_string(void *ilctxt, const char *fmt, ...) { struct encode_context ectxt; int avail_size, data_size, hdr_size = sizeof(struct tsv_header); va_list arg_list; if (!ilctxt) return -EINVAL; msg_encode_start(&ectxt, TSV_TYPE_STRING); tsv_timestamp_write(&ectxt); tsv_qtimer_write(&ectxt); avail_size = (MAX_MSG_SIZE - (ectxt.offset + hdr_size)); va_start(arg_list, fmt); data_size = vscnprintf((ectxt.buff + ectxt.offset + hdr_size), avail_size, fmt, arg_list); va_end(arg_list); tsv_write_header(&ectxt, TSV_TYPE_BYTE_ARRAY, data_size); ectxt.offset += data_size; msg_encode_end(&ectxt); ipc_log_write(ilctxt, &ectxt); return 0; } EXPORT_SYMBOL(ipc_log_string); /** * ipc_log_extract - Reads and deserializes log * * @ctxt: logging context * @buff: buffer to receive the data * @size: size of the buffer * @returns: 0 if no data read; >0 number of bytes read; < 0 error * * If no data is available to be read, then the ilctxt::read_avail * completion is reinitialized. This allows clients to block * until new log data is save. */ int ipc_log_extract(void *ctxt, char *buff, int size) { struct encode_context ectxt; struct decode_context dctxt; void (*deserialize_func)(struct encode_context *ectxt, struct decode_context *dctxt); struct ipc_log_context *ilctxt = (struct ipc_log_context *)ctxt; unsigned long flags; if (size < MAX_MSG_DECODED_SIZE) return -EINVAL; dctxt.output_format = OUTPUT_DEBUGFS; dctxt.buff = buff; dctxt.size = size; read_lock_irqsave(&context_list_lock_lha1, flags); spin_lock(&ilctxt->context_lock_lhb1); while (dctxt.size >= MAX_MSG_DECODED_SIZE && !is_nd_read_empty(ilctxt)) { msg_read(ilctxt, &ectxt); deserialize_func = get_deserialization_func(ilctxt, ectxt.hdr.type); spin_unlock(&ilctxt->context_lock_lhb1); read_unlock_irqrestore(&context_list_lock_lha1, flags); if (deserialize_func) deserialize_func(&ectxt, &dctxt); else pr_err("%s: unknown message 0x%x\n", __func__, ectxt.hdr.type); read_lock_irqsave(&context_list_lock_lha1, flags); spin_lock(&ilctxt->context_lock_lhb1); } if ((size - dctxt.size) == 0) reinit_completion(&ilctxt->read_avail); spin_unlock(&ilctxt->context_lock_lhb1); read_unlock_irqrestore(&context_list_lock_lha1, flags); return size - dctxt.size; } EXPORT_SYMBOL(ipc_log_extract); /* * Helper funtion used to read data from a message context. * * @ectxt context initialized by calling msg_read() * @data data to read * @size number of bytes of data to read */ static void tsv_read_data(struct encode_context *ectxt, void *data, uint32_t size) { BUG_ON((ectxt->offset + size) > MAX_MSG_SIZE); memcpy(data, (ectxt->buff + ectxt->offset), size); ectxt->offset += size; } /* * Helper function that reads a type from the context and updates the * context pointers. * * @ectxt context initialized by calling msg_read() * @hdr type header */ static void tsv_read_header(struct encode_context *ectxt, struct tsv_header *hdr) { BUG_ON((ectxt->offset + sizeof(*hdr)) > MAX_MSG_SIZE); memcpy(hdr, (ectxt->buff + ectxt->offset), sizeof(*hdr)); ectxt->offset += sizeof(*hdr); } /* * Reads a timestamp. * * @ectxt context initialized by calling msg_read() * @dctxt deserialization context * @format output format (appended to %6u.09u timestamp format) */ void tsv_timestamp_read(struct encode_context *ectxt, struct decode_context *dctxt, const char *format) { struct tsv_header hdr; uint64_t val; unsigned long nanosec_rem; tsv_read_header(ectxt, &hdr); BUG_ON(hdr.type != TSV_TYPE_TIMESTAMP); tsv_read_data(ectxt, &val, sizeof(val)); nanosec_rem = do_div(val, 1000000000U); IPC_SPRINTF_DECODE(dctxt, "[%6u.%09lu%s/", (unsigned)val, nanosec_rem, format); } EXPORT_SYMBOL(tsv_timestamp_read); /* * Reads a QTimer timestamp. * * @ectxt context initialized by calling msg_read() * @dctxt deserialization context * @format output format (appended to %#18llx timestamp format) */ void tsv_qtimer_read(struct encode_context *ectxt, struct decode_context *dctxt, const char *format) { struct tsv_header hdr; uint64_t val; tsv_read_header(ectxt, &hdr); BUG_ON(hdr.type != TSV_TYPE_QTIMER); tsv_read_data(ectxt, &val, sizeof(val)); /* * This gives 16 hex digits of output. The # prefix prepends * a 0x, and these characters count as part of the number. */ IPC_SPRINTF_DECODE(dctxt, "%#18llx]%s", val, format); } EXPORT_SYMBOL(tsv_qtimer_read); /* * Reads a data pointer. * * @ectxt context initialized by calling msg_read() * @dctxt deserialization context * @format output format */ void tsv_pointer_read(struct encode_context *ectxt, struct decode_context *dctxt, const char *format) { struct tsv_header hdr; void *val; tsv_read_header(ectxt, &hdr); BUG_ON(hdr.type != TSV_TYPE_POINTER); tsv_read_data(ectxt, &val, sizeof(val)); IPC_SPRINTF_DECODE(dctxt, format, val); } EXPORT_SYMBOL(tsv_pointer_read); /* * Reads a 32-bit integer value. * * @ectxt context initialized by calling msg_read() * @dctxt deserialization context * @format output format */ int32_t tsv_int32_read(struct encode_context *ectxt, struct decode_context *dctxt, const char *format) { struct tsv_header hdr; int32_t val; tsv_read_header(ectxt, &hdr); BUG_ON(hdr.type != TSV_TYPE_INT32); tsv_read_data(ectxt, &val, sizeof(val)); IPC_SPRINTF_DECODE(dctxt, format, val); return val; } EXPORT_SYMBOL(tsv_int32_read); /* * Reads a byte array/string. * * @ectxt context initialized by calling msg_read() * @dctxt deserialization context * @format output format */ void tsv_byte_array_read(struct encode_context *ectxt, struct decode_context *dctxt, const char *format) { struct tsv_header hdr; tsv_read_header(ectxt, &hdr); BUG_ON(hdr.type != TSV_TYPE_BYTE_ARRAY); tsv_read_data(ectxt, dctxt->buff, hdr.size); dctxt->buff += hdr.size; dctxt->size -= hdr.size; } EXPORT_SYMBOL(tsv_byte_array_read); int add_deserialization_func(void *ctxt, int type, void (*dfunc)(struct encode_context *, struct decode_context *)) { struct ipc_log_context *ilctxt = (struct ipc_log_context *)ctxt; struct dfunc_info *df_info; unsigned long flags; if (!ilctxt || !dfunc) return -EINVAL; df_info = kmalloc(sizeof(struct dfunc_info), GFP_KERNEL); if (!df_info) return -ENOSPC; read_lock_irqsave(&context_list_lock_lha1, flags); spin_lock(&ilctxt->context_lock_lhb1); df_info->type = type; df_info->dfunc = dfunc; list_add_tail(&df_info->list, &ilctxt->dfunc_info_list); spin_unlock(&ilctxt->context_lock_lhb1); read_unlock_irqrestore(&context_list_lock_lha1, flags); return 0; } EXPORT_SYMBOL(add_deserialization_func); static void *get_deserialization_func(struct ipc_log_context *ilctxt, int type) { struct dfunc_info *df_info = NULL; if (!ilctxt) return NULL; list_for_each_entry(df_info, &ilctxt->dfunc_info_list, list) { if (df_info->type == type) return df_info->dfunc; } return NULL; } /** * ipc_log_context_create: Create a debug log context * Should not be called from atomic context * * @max_num_pages: Number of pages of logging space required (max. 10) * @mod_name : Name of the directory entry under DEBUGFS * @user_version : Version number of user-defined message formats * * returns context id on success, NULL on failure */ void *ipc_log_context_create(int max_num_pages, const char *mod_name, uint16_t user_version) { struct ipc_log_context *ctxt; struct ipc_log_page *pg = NULL; int page_cnt; unsigned long flags; ctxt = kzalloc(sizeof(struct ipc_log_context), GFP_KERNEL); if (!ctxt) { pr_err("%s: cannot create ipc_log_context\n", __func__); return 0; } init_completion(&ctxt->read_avail); INIT_LIST_HEAD(&ctxt->page_list); INIT_LIST_HEAD(&ctxt->dfunc_info_list); spin_lock_init(&ctxt->context_lock_lhb1); for (page_cnt = 0; page_cnt < max_num_pages; page_cnt++) { pg = kzalloc(sizeof(struct ipc_log_page), GFP_KERNEL); if (!pg) { pr_err("%s: cannot create ipc_log_page\n", __func__); goto release_ipc_log_context; } pg->hdr.log_id = (uint64_t)(uintptr_t)ctxt; pg->hdr.page_num = LOG_PAGE_FLAG | page_cnt; pg->hdr.ctx_offset = (int64_t)((uint64_t)(uintptr_t)ctxt - (uint64_t)(uintptr_t)&pg->hdr); /* set magic last to signal that page init is complete */ pg->hdr.magic = IPC_LOGGING_MAGIC_NUM; pg->hdr.nmagic = ~(IPC_LOGGING_MAGIC_NUM); spin_lock_irqsave(&ctxt->context_lock_lhb1, flags); list_add_tail(&pg->hdr.list, &ctxt->page_list); spin_unlock_irqrestore(&ctxt->context_lock_lhb1, flags); } ctxt->log_id = (uint64_t)(uintptr_t)ctxt; ctxt->version = IPC_LOG_VERSION; strlcpy(ctxt->name, mod_name, IPC_LOG_MAX_CONTEXT_NAME_LEN); ctxt->user_version = user_version; ctxt->first_page = get_first_page(ctxt); ctxt->last_page = pg; ctxt->write_page = ctxt->first_page; ctxt->read_page = ctxt->first_page; ctxt->nd_read_page = ctxt->first_page; ctxt->write_avail = max_num_pages * LOG_PAGE_DATA_SIZE; ctxt->header_size = sizeof(struct ipc_log_page_header); create_ctx_debugfs(ctxt, mod_name); /* set magic last to signal context init is complete */ ctxt->magic = IPC_LOG_CONTEXT_MAGIC_NUM; ctxt->nmagic = ~(IPC_LOG_CONTEXT_MAGIC_NUM); write_lock_irqsave(&context_list_lock_lha1, flags); list_add_tail(&ctxt->list, &ipc_log_context_list); write_unlock_irqrestore(&context_list_lock_lha1, flags); return (void *)ctxt; release_ipc_log_context: while (page_cnt-- > 0) { pg = get_first_page(ctxt); list_del(&pg->hdr.list); kfree(pg); } kfree(ctxt); return 0; } EXPORT_SYMBOL(ipc_log_context_create); /* * Destroy debug log context * * @ctxt: debug log context created by calling ipc_log_context_create API. */ int ipc_log_context_destroy(void *ctxt) { struct ipc_log_context *ilctxt = (struct ipc_log_context *)ctxt; struct ipc_log_page *pg = NULL; unsigned long flags; if (!ilctxt) return 0; while (!list_empty(&ilctxt->page_list)) { pg = get_first_page(ctxt); list_del(&pg->hdr.list); kfree(pg); } write_lock_irqsave(&context_list_lock_lha1, flags); list_del(&ilctxt->list); write_unlock_irqrestore(&context_list_lock_lha1, flags); debugfs_remove_recursive(ilctxt->dent); kfree(ilctxt); return 0; } EXPORT_SYMBOL(ipc_log_context_destroy); static int __init ipc_logging_init(void) { check_and_create_debugfs(); return 0; } module_init(ipc_logging_init); MODULE_DESCRIPTION("ipc logging"); MODULE_LICENSE("GPL v2");