/* * Copyright (c) 2006-2022, RT-Thread Development Team * * SPDX-License-Identifier: Apache-2.0 * * Change Logs: * Date Author Notes * 2018-08-25 armink the first version */ #include #include "ulog.h" #include "rthw.h" #ifdef ULOG_USING_SYSLOG #include #endif #ifdef ULOG_TIME_USING_TIMESTAMP #include #endif #ifdef ULOG_USING_ASYNC_OUTPUT #include #endif #ifdef RT_USING_ULOG /* the number which is max stored line logs */ #ifndef ULOG_ASYNC_OUTPUT_STORE_LINES #define ULOG_ASYNC_OUTPUT_STORE_LINES (ULOG_ASYNC_OUTPUT_BUF_SIZE * 3 / 2 / 80) #endif #ifdef ULOG_USING_COLOR /** * CSI(Control Sequence Introducer/Initiator) sign * more information on https://en.wikipedia.org/wiki/ANSI_escape_code */ #define CSI_START "\033[" #define CSI_END "\033[0m" /* output log front color */ #define F_BLACK "30m" #define F_RED "31m" #define F_GREEN "32m" #define F_YELLOW "33m" #define F_BLUE "34m" #define F_MAGENTA "35m" #define F_CYAN "36m" #define F_WHITE "37m" /* output log default color definition */ #ifndef ULOG_COLOR_DEBUG #define ULOG_COLOR_DEBUG RT_NULL #endif #ifndef ULOG_COLOR_INFO #define ULOG_COLOR_INFO (F_GREEN) #endif #ifndef ULOG_COLOR_WARN #define ULOG_COLOR_WARN (F_YELLOW) #endif #ifndef ULOG_COLOR_ERROR #define ULOG_COLOR_ERROR (F_RED) #endif #ifndef ULOG_COLOR_ASSERT #define ULOG_COLOR_ASSERT (F_MAGENTA) #endif #endif /* ULOG_USING_COLOR */ #if ULOG_LINE_BUF_SIZE < 80 #error "the log line buffer size must more than 80" #endif struct rt_ulog { rt_bool_t init_ok; rt_bool_t output_lock_enabled; struct rt_mutex output_locker; /* all backends */ rt_slist_t backend_list; /* the thread log's line buffer */ char log_buf_th[ULOG_LINE_BUF_SIZE + 1]; #ifdef ULOG_USING_ISR_LOG /* the ISR log's line buffer */ rt_base_t output_locker_isr_lvl; char log_buf_isr[ULOG_LINE_BUF_SIZE + 1]; #endif /* ULOG_USING_ISR_LOG */ #ifdef ULOG_USING_ASYNC_OUTPUT rt_bool_t async_enabled; rt_rbb_t async_rbb; /* ringbuffer for log_raw function only */ struct rt_ringbuffer *async_rb; rt_thread_t async_th; struct rt_semaphore async_notice; #endif #ifdef ULOG_USING_FILTER struct { /* all tag's level filter */ rt_slist_t tag_lvl_list; /* global filter level, tag and keyword */ rt_uint32_t level; char tag[ULOG_FILTER_TAG_MAX_LEN + 1]; char keyword[ULOG_FILTER_KW_MAX_LEN + 1]; } filter; #endif /* ULOG_USING_FILTER */ }; /* level output info */ static const char * const level_output_info[] = { "A/", RT_NULL, RT_NULL, "E/", "W/", RT_NULL, "I/", "D/", }; #ifdef ULOG_USING_COLOR /* color output info */ static const char * const color_output_info[] = { ULOG_COLOR_ASSERT, RT_NULL, RT_NULL, ULOG_COLOR_ERROR, ULOG_COLOR_WARN, RT_NULL, ULOG_COLOR_INFO, ULOG_COLOR_DEBUG, }; #endif /* ULOG_USING_COLOR */ /* ulog local object */ static struct rt_ulog ulog = { 0 }; rt_size_t ulog_strcpy(rt_size_t cur_len, char *dst, const char *src) { const char *src_old = src; RT_ASSERT(dst); RT_ASSERT(src); while (*src != 0) { /* make sure destination has enough space */ if (cur_len++ < ULOG_LINE_BUF_SIZE) { *dst++ = *src++; } else { break; } } return src - src_old; } rt_size_t ulog_ultoa(char *s, unsigned long int n) { rt_size_t i = 0, j = 0, len = 0; char swap; do { s[len++] = n % 10 + '0'; } while (n /= 10); s[len] = '\0'; /* reverse string */ for (i = 0, j = len - 1; i < j; ++i, --j) { swap = s[i]; s[i] = s[j]; s[j] = swap; } return len; } static void output_unlock(void) { /* earlier stage */ if (ulog.output_lock_enabled == RT_FALSE) { return; } /* If the scheduler is started and in thread context */ if (rt_interrupt_get_nest() == 0 && rt_thread_self() != RT_NULL) { rt_mutex_release(&ulog.output_locker); } else { #ifdef ULOG_USING_ISR_LOG rt_hw_interrupt_enable(ulog.output_locker_isr_lvl); #endif } } static void output_lock(void) { /* earlier stage */ if (ulog.output_lock_enabled == RT_FALSE) { return; } /* If the scheduler is started and in thread context */ if (rt_interrupt_get_nest() == 0 && rt_thread_self() != RT_NULL) { rt_mutex_take(&ulog.output_locker, RT_WAITING_FOREVER); } else { #ifdef ULOG_USING_ISR_LOG ulog.output_locker_isr_lvl = rt_hw_interrupt_disable(); #endif } } void ulog_output_lock_enabled(rt_bool_t enabled) { ulog.output_lock_enabled = enabled; } static char *get_log_buf(void) { /* is in thread context */ if (rt_interrupt_get_nest() == 0) { return ulog.log_buf_th; } else { #ifdef ULOG_USING_ISR_LOG return ulog.log_buf_isr; #else rt_kprintf("Error: Current mode not supported run in ISR. Please enable ULOG_USING_ISR_LOG.\n"); return RT_NULL; #endif } } RT_WEAK rt_size_t ulog_formater(char *log_buf, rt_uint32_t level, const char *tag, rt_bool_t newline, const char *format, va_list args) { /* the caller has locker, so it can use static variable for reduce stack usage */ static rt_size_t log_len, newline_len; static int fmt_result; RT_ASSERT(log_buf); RT_ASSERT(level <= LOG_LVL_DBG); RT_ASSERT(tag); RT_ASSERT(format); log_len = 0; newline_len = rt_strlen(ULOG_NEWLINE_SIGN); #ifdef ULOG_USING_COLOR /* add CSI start sign and color info */ if (color_output_info[level]) { log_len += ulog_strcpy(log_len, log_buf + log_len, CSI_START); log_len += ulog_strcpy(log_len, log_buf + log_len, color_output_info[level]); } #endif /* ULOG_USING_COLOR */ log_buf[log_len] = '\0'; #ifdef ULOG_OUTPUT_TIME /* add time info */ { #ifdef ULOG_TIME_USING_TIMESTAMP static struct timeval now; static struct tm *tm, tm_tmp; static rt_bool_t check_usec_support = RT_FALSE, usec_is_support = RT_FALSE; if (gettimeofday(&now, RT_NULL) >= 0) { time_t t = now.tv_sec; tm = localtime_r(&t, &tm_tmp); /* show the time format MM-DD HH:MM:SS */ rt_snprintf(log_buf + log_len, ULOG_LINE_BUF_SIZE - log_len, "%02d-%02d %02d:%02d:%02d", tm->tm_mon + 1, tm->tm_mday, tm->tm_hour, tm->tm_min, tm->tm_sec); /* check the microseconds support when kernel is startup */ if (!check_usec_support && rt_thread_self() != RT_NULL) { long old_usec = now.tv_usec; /* delay some time for wait microseconds changed */ rt_thread_mdelay(10); gettimeofday(&now, RT_NULL); check_usec_support = RT_TRUE; /* the microseconds is not equal between two gettimeofday calls */ if (now.tv_usec != old_usec) usec_is_support = RT_TRUE; } if (usec_is_support) { /* show the millisecond */ log_len += rt_strlen(log_buf + log_len); rt_snprintf(log_buf + log_len, ULOG_LINE_BUF_SIZE - log_len, ".%03d", now.tv_usec / 1000); } } #else static rt_size_t tick_len = 0; log_buf[log_len] = '['; tick_len = ulog_ultoa(log_buf + log_len + 1, rt_tick_get()); log_buf[log_len + 1 + tick_len] = ']'; log_buf[log_len + 1 + tick_len + 1] = '\0'; #endif /* ULOG_TIME_USING_TIMESTAMP */ log_len += rt_strlen(log_buf + log_len); } #endif /* ULOG_OUTPUT_TIME */ #ifdef ULOG_OUTPUT_LEVEL #ifdef ULOG_OUTPUT_TIME log_len += ulog_strcpy(log_len, log_buf + log_len, " "); #endif /* add level info */ log_len += ulog_strcpy(log_len, log_buf + log_len, level_output_info[level]); #endif /* ULOG_OUTPUT_LEVEL */ #ifdef ULOG_OUTPUT_TAG #if !defined(ULOG_OUTPUT_LEVEL) && defined(ULOG_OUTPUT_TIME) log_len += ulog_strcpy(log_len, log_buf + log_len, " "); #endif /* add tag info */ log_len += ulog_strcpy(log_len, log_buf + log_len, tag); #endif /* ULOG_OUTPUT_TAG */ #ifdef ULOG_OUTPUT_THREAD_NAME /* add thread info */ { #if defined(ULOG_OUTPUT_TIME) || defined(ULOG_OUTPUT_LEVEL) || defined(ULOG_OUTPUT_TAG) log_len += ulog_strcpy(log_len, log_buf + log_len, " "); #endif /* is not in interrupt context */ if (rt_interrupt_get_nest() == 0) { rt_size_t name_len = 0; const char *thread_name = "N/A"; if (rt_thread_self()) { thread_name = rt_thread_self()->name; } name_len = rt_strnlen(thread_name, RT_NAME_MAX); rt_strncpy(log_buf + log_len, thread_name, name_len); log_len += name_len; } else { log_len += ulog_strcpy(log_len, log_buf + log_len, "ISR"); } } #endif /* ULOG_OUTPUT_THREAD_NAME */ log_len += ulog_strcpy(log_len, log_buf + log_len, ": "); fmt_result = rt_vsnprintf(log_buf + log_len, ULOG_LINE_BUF_SIZE - log_len, format, args); /* calculate log length */ if ((log_len + fmt_result <= ULOG_LINE_BUF_SIZE) && (fmt_result > -1)) { log_len += fmt_result; } else { /* using max length */ log_len = ULOG_LINE_BUF_SIZE; } /* overflow check and reserve some space for CSI end sign and newline sign */ #ifdef ULOG_USING_COLOR if (log_len + (sizeof(CSI_END) - 1) + newline_len > ULOG_LINE_BUF_SIZE) { /* using max length */ log_len = ULOG_LINE_BUF_SIZE; /* reserve some space for CSI end sign */ log_len -= (sizeof(CSI_END) - 1); #else if (log_len + newline_len > ULOG_LINE_BUF_SIZE) { /* using max length */ log_len = ULOG_LINE_BUF_SIZE; #endif /* ULOG_USING_COLOR */ /* reserve some space for newline sign */ log_len -= newline_len; } /* package newline sign */ if (newline) { log_len += ulog_strcpy(log_len, log_buf + log_len, ULOG_NEWLINE_SIGN); } #ifdef ULOG_USING_COLOR /* add CSI end sign */ if (color_output_info[level]) { log_len += ulog_strcpy(log_len, log_buf + log_len, CSI_END); } #endif /* ULOG_USING_COLOR */ return log_len; } void ulog_output_to_all_backend(rt_uint32_t level, const char *tag, rt_bool_t is_raw, const char *log, rt_size_t size) { rt_slist_t *node; ulog_backend_t backend; if (!ulog.init_ok) return; /* if there is no backend */ if (!rt_slist_first(&ulog.backend_list)) { rt_kputs(log); return; } /* output for all backends */ for (node = rt_slist_first(&ulog.backend_list); node; node = rt_slist_next(node)) { backend = rt_slist_entry(node, struct ulog_backend, list); if (backend->out_level < level) { continue; } #if !defined(ULOG_USING_COLOR) || defined(ULOG_USING_SYSLOG) backend->output(backend, level, tag, is_raw, log, size); #else if (backend->filter && backend->filter(backend, level, tag, is_raw, log, size) == RT_FALSE) { /* backend's filter is not match, so skip output */ continue; } if (backend->support_color || is_raw) { backend->output(backend, level, tag, is_raw, log, size); } else { /* recalculate the log start address and log size when backend not supported color */ rt_size_t color_info_len = 0, output_size = size; const char *output_log = log; if (color_output_info[level] != RT_NULL) color_info_len = rt_strlen(color_output_info[level]); if (color_info_len) { rt_size_t color_hdr_len = rt_strlen(CSI_START) + color_info_len; output_log += color_hdr_len; output_size -= (color_hdr_len + (sizeof(CSI_END) - 1)); } backend->output(backend, level, tag, is_raw, output_log, output_size); } #endif /* !defined(ULOG_USING_COLOR) || defined(ULOG_USING_SYSLOG) */ } } static void do_output(rt_uint32_t level, const char *tag, rt_bool_t is_raw, const char *log_buf, rt_size_t log_len) { #ifdef ULOG_USING_ASYNC_OUTPUT if (is_raw == RT_FALSE) { rt_rbb_blk_t log_blk; ulog_frame_t log_frame; /* allocate log frame */ log_blk = rt_rbb_blk_alloc(ulog.async_rbb, RT_ALIGN(sizeof(struct ulog_frame) + log_len, RT_ALIGN_SIZE)); if (log_blk) { /* package the log frame */ log_frame = (ulog_frame_t) log_blk->buf; log_frame->magic = ULOG_FRAME_MAGIC; log_frame->is_raw = is_raw; log_frame->level = level; log_frame->log_len = log_len; log_frame->tag = tag; log_frame->log = (const char *)log_blk->buf + sizeof(struct ulog_frame); /* copy log data */ rt_memcpy(log_blk->buf + sizeof(struct ulog_frame), log_buf, log_len); /* put the block */ rt_rbb_blk_put(log_blk); /* send a notice */ rt_sem_release(&ulog.async_notice); } else { static rt_bool_t already_output = RT_FALSE; if (already_output == RT_FALSE) { rt_kprintf("Warning: There is no enough buffer for saving async log," " please increase the ULOG_ASYNC_OUTPUT_BUF_SIZE option.\n"); already_output = RT_TRUE; } } } else if (ulog.async_rb) { rt_ringbuffer_put(ulog.async_rb, (const rt_uint8_t *)log_buf, log_len); /* send a notice */ rt_sem_release(&ulog.async_notice); } #else /* is in thread context */ if (rt_interrupt_get_nest() == 0) { /* output to all backends */ ulog_output_to_all_backend(level, tag, is_raw, log_buf, log_len); } else { #ifdef ULOG_BACKEND_USING_CONSOLE /* We can't ensure that all backends support ISR context output. * So only using rt_kprintf when context is ISR */ extern void ulog_console_backend_output(struct ulog_backend *backend, rt_uint32_t level, const char *tag, rt_bool_t is_raw, const char *log, rt_size_t len); ulog_console_backend_output(RT_NULL, level, tag, is_raw, log_buf, log_len); #endif /* ULOG_BACKEND_USING_CONSOLE */ } #endif /* ULOG_USING_ASYNC_OUTPUT */ } /** * output the log by variable argument list * * @param level level * @param tag tag * @param newline has_newline * @param format output format * @param args variable argument list */ void ulog_voutput(rt_uint32_t level, const char *tag, rt_bool_t newline, const char *format, va_list args) { static rt_bool_t ulog_voutput_recursion = RT_FALSE; char *log_buf = RT_NULL; rt_size_t log_len = 0; RT_ASSERT(tag); RT_ASSERT(format); #ifndef ULOG_USING_SYSLOG RT_ASSERT(level <= LOG_LVL_DBG); #else RT_ASSERT(LOG_PRI(level) <= LOG_DEBUG); #endif /* ULOG_USING_SYSLOG */ if (!ulog.init_ok) { return; } #ifdef ULOG_USING_FILTER /* level filter */ #ifndef ULOG_USING_SYSLOG if (level > ulog.filter.level || level > ulog_tag_lvl_filter_get(tag)) { return; } #else if (((LOG_MASK(LOG_PRI(level)) & ulog.filter.level) == 0) || ((LOG_MASK(LOG_PRI(level)) & ulog_tag_lvl_filter_get(tag)) == 0)) { return; } #endif /* ULOG_USING_SYSLOG */ else if (!rt_strstr(tag, ulog.filter.tag)) { return; } #endif /* ULOG_USING_FILTER */ /* get log buffer */ log_buf = get_log_buf(); /* lock output */ output_lock(); /* If there is a recursion, we use a simple way */ if (ulog_voutput_recursion == RT_TRUE) { rt_kprintf(format, args); if(newline == RT_TRUE) { rt_kprintf(ULOG_NEWLINE_SIGN); } output_unlock(); return; } ulog_voutput_recursion = RT_TRUE; #ifndef ULOG_USING_SYSLOG log_len = ulog_formater(log_buf, level, tag, newline, format, args); #else extern rt_size_t syslog_formater(char *log_buf, rt_uint8_t level, const char *tag, rt_bool_t newline, const char *format, va_list args); log_len = syslog_formater(log_buf, level, tag, newline, format, args); #endif /* ULOG_USING_SYSLOG */ #ifdef ULOG_USING_FILTER /* keyword filter */ if (ulog.filter.keyword[0] != '\0') { /* add string end sign */ log_buf[log_len] = '\0'; /* find the keyword */ if (!rt_strstr(log_buf, ulog.filter.keyword)) { ulog_voutput_recursion = RT_FALSE; /* unlock output */ output_unlock(); return; } } #endif /* ULOG_USING_FILTER */ /* do log output */ do_output(level, tag, RT_FALSE, log_buf, log_len); ulog_voutput_recursion = RT_FALSE; /* unlock output */ output_unlock(); } /** * output the log * * @param level level * @param tag tag * @param newline has newline * @param format output format * @param ... args */ void ulog_output(rt_uint32_t level, const char *tag, rt_bool_t newline, const char *format, ...) { va_list args; /* args point to the first variable parameter */ va_start(args, format); ulog_voutput(level, tag, newline, format, args); va_end(args); } /** * output RAW string format log * * @param format output format * @param ... args */ void ulog_raw(const char *format, ...) { rt_size_t log_len = 0; char *log_buf = RT_NULL; va_list args; int fmt_result; RT_ASSERT(ulog.init_ok); #ifdef ULOG_USING_ASYNC_OUTPUT if (ulog.async_rb == RT_NULL) { ulog.async_rb = rt_ringbuffer_create(ULOG_ASYNC_OUTPUT_BUF_SIZE); } #endif /* get log buffer */ log_buf = get_log_buf(); /* lock output */ output_lock(); /* args point to the first variable parameter */ va_start(args, format); fmt_result = rt_vsnprintf(log_buf, ULOG_LINE_BUF_SIZE, format, args); va_end(args); /* calculate log length */ if ((fmt_result > -1) && (fmt_result <= ULOG_LINE_BUF_SIZE)) { log_len = fmt_result; } else { log_len = ULOG_LINE_BUF_SIZE; } /* do log output */ do_output(LOG_LVL_DBG, RT_NULL, RT_TRUE, log_buf, log_len); /* unlock output */ output_unlock(); } /** * dump the hex format data to log * * @param tag name for hex object, it will show on log header * @param width hex number for every line, such as: 16, 32 * @param buf hex buffer * @param size buffer size */ void ulog_hexdump(const char *tag, rt_size_t width, rt_uint8_t *buf, rt_size_t size) { #define __is_print(ch) ((unsigned int)((ch) - ' ') < 127u - ' ') rt_size_t i, j; rt_size_t log_len = 0, name_len = rt_strlen(tag); #ifdef ULOG_OUTPUT_TIME rt_size_t time_head_len = 0; #endif char *log_buf = RT_NULL, dump_string[8]; int fmt_result; RT_ASSERT(ulog.init_ok); #ifdef ULOG_USING_FILTER /* level filter */ #ifndef ULOG_USING_SYSLOG if (LOG_LVL_DBG > ulog.filter.level || LOG_LVL_DBG > ulog_tag_lvl_filter_get(tag)) { return; } #else if ((LOG_MASK(LOG_DEBUG) & ulog.filter.level) == 0) { return; } #endif /* ULOG_USING_SYSLOG */ else if (!rt_strstr(tag, ulog.filter.tag)) { /* tag filter */ return; } #endif /* ULOG_USING_FILTER */ #ifdef ULOG_USING_ASYNC_OUTPUT if (ulog.async_rb == RT_NULL) { ulog.async_rb = rt_ringbuffer_create(ULOG_ASYNC_OUTPUT_BUF_SIZE); } #endif /* get log buffer */ log_buf = get_log_buf(); /* lock output */ output_lock(); for (i = 0, log_len = 0; i < size; i += width) { /* package header */ if (i == 0) { #ifdef ULOG_OUTPUT_TIME /* add time info */ #ifdef ULOG_TIME_USING_TIMESTAMP static time_t now; static struct tm *tm, tm_tmp; now = time(RT_NULL); tm = gmtime_r(&now, &tm_tmp); #ifdef RT_USING_SOFT_RTC rt_snprintf(log_buf + log_len, ULOG_LINE_BUF_SIZE - log_len, "%02d-%02d %02d:%02d:%02d.%03d ", tm->tm_mon + 1, tm->tm_mday, tm->tm_hour, tm->tm_min, tm->tm_sec, rt_tick_get() % 1000); #else rt_snprintf(log_buf + log_len, ULOG_LINE_BUF_SIZE - log_len, "%02d-%02d %02d:%02d:%02d ", tm->tm_mon + 1, tm->tm_mday, tm->tm_hour, tm->tm_min, tm->tm_sec); #endif /* RT_USING_SOFT_RTC */ #else static rt_size_t tick_len = 0; log_buf[log_len] = '['; tick_len = ulog_ultoa(log_buf + log_len + 1, rt_tick_get()); log_buf[log_len + 1 + tick_len] = ']'; log_buf[log_len + 2 + tick_len] = ' '; log_buf[log_len + 3 + tick_len] = '\0'; #endif /* ULOG_TIME_USING_TIMESTAMP */ time_head_len = rt_strlen(log_buf + log_len); log_len += time_head_len; #endif /* ULOG_OUTPUT_TIME */ log_len += ulog_strcpy(log_len, log_buf + log_len, "D/HEX "); log_len += ulog_strcpy(log_len, log_buf + log_len, tag); log_len += ulog_strcpy(log_len, log_buf + log_len, ": "); } else { log_len = 6 + name_len + 2; #ifdef ULOG_OUTPUT_TIME log_len += time_head_len; #endif rt_memset(log_buf, ' ', log_len); } fmt_result = rt_snprintf(log_buf + log_len, ULOG_LINE_BUF_SIZE, "%04X-%04X: ", i, i + width - 1); /* calculate log length */ if ((fmt_result > -1) && (fmt_result <= ULOG_LINE_BUF_SIZE)) { log_len += fmt_result; } else { log_len = ULOG_LINE_BUF_SIZE; } /* dump hex */ for (j = 0; j < width; j++) { if (i + j < size) { rt_snprintf(dump_string, sizeof(dump_string), "%02X ", buf[i + j]); } else { rt_strncpy(dump_string, " ", sizeof(dump_string)); } log_len += ulog_strcpy(log_len, log_buf + log_len, dump_string); if ((j + 1) % 8 == 0) { log_len += ulog_strcpy(log_len, log_buf + log_len, " "); } } log_len += ulog_strcpy(log_len, log_buf + log_len, " "); /* dump char for hex */ for (j = 0; j < width; j++) { if (i + j < size) { rt_snprintf(dump_string, sizeof(dump_string), "%c", __is_print(buf[i + j]) ? buf[i + j] : '.'); log_len += ulog_strcpy(log_len, log_buf + log_len, dump_string); } } /* overflow check and reserve some space for newline sign */ if (log_len + rt_strlen(ULOG_NEWLINE_SIGN) > ULOG_LINE_BUF_SIZE) { log_len = ULOG_LINE_BUF_SIZE - rt_strlen(ULOG_NEWLINE_SIGN); } /* package newline sign */ log_len += ulog_strcpy(log_len, log_buf + log_len, ULOG_NEWLINE_SIGN); /*add string end sign*/ log_buf[log_len] = '\0'; /* do log output */ do_output(LOG_LVL_DBG, RT_NULL, RT_TRUE, log_buf, log_len); } /* unlock output */ output_unlock(); } #ifdef ULOG_USING_FILTER /** * Set the filter's level by different backend. * The log on this backend which level is less than it will stop output. * * @param be_name backend name * @param level The filter level. When the level is LOG_FILTER_LVL_SILENT, the log enter silent mode. * When the level is LOG_FILTER_LVL_ALL, it will remove this tag's level filer. * Then all level log will resume output. * * @return 0 : success * -10: level is out of range */ int ulog_be_lvl_filter_set(const char *be_name, rt_uint32_t level) { rt_slist_t *node = RT_NULL; ulog_backend_t backend; int result = RT_EOK; if (level > LOG_FILTER_LVL_ALL) return -RT_EINVAL; if (!ulog.init_ok) return result; for (node = rt_slist_first(&ulog.backend_list); node; node = rt_slist_next(node)) { backend = rt_slist_entry(node, struct ulog_backend, list); if (rt_strncmp(backend->name, be_name, RT_NAME_MAX) == 0) { backend->out_level = level; } } return result; } /** * Set the filter's level by different tag. * The log on this tag which level is less than it will stop output. * * example: * // the example tag log enter silent mode * ulog_set_filter_lvl("example", LOG_FILTER_LVL_SILENT); * // the example tag log which level is less than INFO level will stop output * ulog_set_filter_lvl("example", LOG_LVL_INFO); * // remove example tag's level filter, all level log will resume output * ulog_set_filter_lvl("example", LOG_FILTER_LVL_ALL); * * @param tag log tag * @param level The filter level. When the level is LOG_FILTER_LVL_SILENT, the log enter silent mode. * When the level is LOG_FILTER_LVL_ALL, it will remove this tag's level filer. * Then all level log will resume output. * * @return 0 : success * -5 : no memory * -10: level is out of range */ int ulog_tag_lvl_filter_set(const char *tag, rt_uint32_t level) { rt_slist_t *node; ulog_tag_lvl_filter_t tag_lvl = RT_NULL; int result = RT_EOK; if (level > LOG_FILTER_LVL_ALL) return -RT_EINVAL; if (!ulog.init_ok) return result; /* lock output */ output_lock(); /* find the tag in list */ for (node = rt_slist_first(ulog_tag_lvl_list_get()); node; node = rt_slist_next(node)) { tag_lvl = rt_slist_entry(node, struct ulog_tag_lvl_filter, list); if (!rt_strncmp(tag_lvl->tag, tag, ULOG_FILTER_TAG_MAX_LEN)) { break; } else { tag_lvl = RT_NULL; } } /* find OK */ if (tag_lvl) { if (level == LOG_FILTER_LVL_ALL) { /* remove current tag's level filter when input level is the lowest level */ rt_slist_remove(ulog_tag_lvl_list_get(), &tag_lvl->list); rt_free(tag_lvl); } else { /* update level */ tag_lvl->level = level; } } else { /* only add the new tag's level filer when level is not LOG_FILTER_LVL_ALL */ if (level != LOG_FILTER_LVL_ALL) { /* new a tag's level filter */ tag_lvl = (ulog_tag_lvl_filter_t)rt_malloc(sizeof(struct ulog_tag_lvl_filter)); if (tag_lvl) { rt_memset(tag_lvl->tag, 0 , sizeof(tag_lvl->tag)); rt_strncpy(tag_lvl->tag, tag, ULOG_FILTER_TAG_MAX_LEN); tag_lvl->level = level; rt_slist_append(ulog_tag_lvl_list_get(), &tag_lvl->list); } else { result = -RT_ENOMEM; } } } /* unlock output */ output_unlock(); return result; } /** * get the level on tag's level filer * * @param tag log tag * * @return It will return the lowest level when tag was not found. * Other level will return when tag was found. */ rt_uint32_t ulog_tag_lvl_filter_get(const char *tag) { rt_slist_t *node; ulog_tag_lvl_filter_t tag_lvl = RT_NULL; rt_uint32_t level = LOG_FILTER_LVL_ALL; if (!ulog.init_ok) return level; /* lock output */ output_lock(); /* find the tag in list */ for (node = rt_slist_first(ulog_tag_lvl_list_get()); node; node = rt_slist_next(node)) { tag_lvl = rt_slist_entry(node, struct ulog_tag_lvl_filter, list); if (!rt_strncmp(tag_lvl->tag, tag, ULOG_FILTER_TAG_MAX_LEN)) { level = tag_lvl->level; break; } } /* unlock output */ output_unlock(); return level; } /** * get the tag's level list on filter * * @return tag's level list */ rt_slist_t *ulog_tag_lvl_list_get(void) { return &ulog.filter.tag_lvl_list; } /** * set log global filter level * * @param level log level: LOG_LVL_ASSERT, LOG_LVL_ERROR, LOG_LVL_WARNING, LOG_LVL_INFO, LOG_LVL_DBG * LOG_FILTER_LVL_SILENT: disable all log output, except assert level * LOG_FILTER_LVL_ALL: enable all log output */ void ulog_global_filter_lvl_set(rt_uint32_t level) { RT_ASSERT(level <= LOG_FILTER_LVL_ALL); ulog.filter.level = level; } /** * get log global filter level * * @return log level: LOG_LVL_ASSERT, LOG_LVL_ERROR, LOG_LVL_WARNING, LOG_LVL_INFO, LOG_LVL_DBG * LOG_FILTER_LVL_SILENT: disable all log output, except assert level * LOG_FILTER_LVL_ALL: enable all log output */ rt_uint32_t ulog_global_filter_lvl_get(void) { return ulog.filter.level; } /** * set log global filter tag * * @param tag tag */ void ulog_global_filter_tag_set(const char *tag) { RT_ASSERT(tag); rt_strncpy(ulog.filter.tag, tag, ULOG_FILTER_TAG_MAX_LEN); } /** * get log global filter tag * * @return tag */ const char *ulog_global_filter_tag_get(void) { return ulog.filter.tag; } /** * set log global filter keyword * * @param keyword keyword */ void ulog_global_filter_kw_set(const char *keyword) { RT_ASSERT(keyword); rt_strncpy(ulog.filter.keyword, keyword, ULOG_FILTER_KW_MAX_LEN); } /** * get log global filter keyword * * @return keyword */ const char *ulog_global_filter_kw_get(void) { return ulog.filter.keyword; } #ifdef RT_USING_FINSH #include static void _print_lvl_info(void) { #ifndef ULOG_USING_SYSLOG rt_kprintf("Assert : 0\n"); rt_kprintf("Error : 3\n"); rt_kprintf("Warning : 4\n"); rt_kprintf("Info : 6\n"); rt_kprintf("Debug : 7\n"); #else rt_kprintf("EMERG : 1 (1 << 0)\n"); rt_kprintf("ALERT : 2 (1 << 1)\n"); rt_kprintf("CRIT : 4 (1 << 2)\n"); rt_kprintf("ERR : 8 (1 << 3)\n"); rt_kprintf("WARNING : 16 (1 << 4)\n"); rt_kprintf("NOTICE : 32 (1 << 5)\n"); rt_kprintf("INFO : 64 (1 << 6)\n"); rt_kprintf("DEBUG : 128 (1 << 7)\n"); #endif /* ULOG_USING_SYSLOG */ } static void ulog_be_lvl(uint8_t argc, char **argv) { if (argc > 2) { if ((atoi(argv[2]) <= LOG_FILTER_LVL_ALL) && (atoi(argv[2]) >= 0)) { ulog_be_lvl_filter_set(argv[1], atoi(argv[2])); } else { rt_kprintf("Please input correct level (0-%d).\n", LOG_FILTER_LVL_ALL); } } else { rt_kprintf("Please input: ulog_be_lvl .\n"); _print_lvl_info(); } } MSH_CMD_EXPORT(ulog_be_lvl, Set ulog filter level by different backend.); static void ulog_tag_lvl(uint8_t argc, char **argv) { if (argc > 2) { if ((atoi(argv[2]) <= LOG_FILTER_LVL_ALL) && (atoi(argv[2]) >= 0)) { ulog_tag_lvl_filter_set(argv[1], atoi(argv[2])); } else { rt_kprintf("Please input correct level (0-%d).\n", LOG_FILTER_LVL_ALL); } } else { rt_kprintf("Please input: ulog_tag_lvl .\n"); _print_lvl_info(); } } MSH_CMD_EXPORT(ulog_tag_lvl, Set ulog filter level by different tag.); static void ulog_lvl(uint8_t argc, char **argv) { if (argc > 1) { if ((atoi(argv[1]) <= LOG_FILTER_LVL_ALL) && (atoi(argv[1]) >= 0)) { ulog_global_filter_lvl_set(atoi(argv[1])); } else { rt_kprintf("Please input correct level (0-%d).\n", LOG_FILTER_LVL_ALL); } } else { rt_kprintf("Please input: ulog_lvl .\n"); _print_lvl_info(); } } MSH_CMD_EXPORT(ulog_lvl, Set ulog global filter level.); static void ulog_tag(uint8_t argc, char **argv) { if (argc > 1) { if (rt_strlen(argv[1]) <= ULOG_FILTER_TAG_MAX_LEN) { ulog_global_filter_tag_set(argv[1]); } else { rt_kprintf("The tag length is too long. Max is %d.\n", ULOG_FILTER_TAG_MAX_LEN); } } else { ulog_global_filter_tag_set(""); } } MSH_CMD_EXPORT(ulog_tag, Set ulog global filter tag); static void ulog_kw(uint8_t argc, char **argv) { if (argc > 1) { if (rt_strlen(argv[1]) <= ULOG_FILTER_KW_MAX_LEN) { ulog_global_filter_kw_set(argv[1]); } else { rt_kprintf("The keyword length is too long. Max is %d.\n", ULOG_FILTER_KW_MAX_LEN); } } else { ulog_global_filter_kw_set(""); } } MSH_CMD_EXPORT(ulog_kw, Set ulog global filter keyword); static void ulog_filter(uint8_t argc, char **argv) { #ifndef ULOG_USING_SYSLOG const char *lvl_name[] = { "Assert ", "Error ", "Error ", "Error ", "Warning", "Info ", "Info ", "Debug " }; #endif const char *tag = ulog_global_filter_tag_get(), *kw = ulog_global_filter_kw_get(); rt_slist_t *node; ulog_tag_lvl_filter_t tag_lvl = RT_NULL; rt_kprintf("--------------------------------------\n"); rt_kprintf("ulog global filter:\n"); #ifndef ULOG_USING_SYSLOG rt_kprintf("level : %s\n", lvl_name[ulog_global_filter_lvl_get()]); #else rt_kprintf("level : %d\n", ulog_global_filter_lvl_get()); #endif rt_kprintf("tag : %s\n", rt_strlen(tag) == 0 ? "NULL" : tag); rt_kprintf("keyword : %s\n", rt_strlen(kw) == 0 ? "NULL" : kw); rt_kprintf("--------------------------------------\n"); rt_kprintf("ulog tag's level filter:\n"); if (rt_slist_isempty(ulog_tag_lvl_list_get())) { rt_kprintf("settings not found\n"); } else { /* lock output */ output_lock(); /* show the tag level list */ for (node = rt_slist_first(ulog_tag_lvl_list_get()); node; node = rt_slist_next(node)) { tag_lvl = rt_slist_entry(node, struct ulog_tag_lvl_filter, list); rt_kprintf("%-*.s: ", ULOG_FILTER_TAG_MAX_LEN, tag_lvl->tag); #ifndef ULOG_USING_SYSLOG rt_kprintf("%s\n", lvl_name[tag_lvl->level]); #else rt_kprintf("%d\n", tag_lvl->level); #endif } /* unlock output */ output_unlock(); } } MSH_CMD_EXPORT(ulog_filter, Show ulog filter settings); #endif /* RT_USING_FINSH */ #endif /* ULOG_USING_FILTER */ rt_err_t ulog_backend_register(ulog_backend_t backend, const char *name, rt_bool_t support_color) { rt_base_t level; RT_ASSERT(backend); RT_ASSERT(name); RT_ASSERT(ulog.init_ok); RT_ASSERT(backend->output); if (backend->init) { backend->init(backend); } backend->support_color = support_color; backend->out_level = LOG_FILTER_LVL_ALL; rt_strncpy(backend->name, name, RT_NAME_MAX); level = rt_hw_interrupt_disable(); rt_slist_append(&ulog.backend_list, &backend->list); rt_hw_interrupt_enable(level); return RT_EOK; } rt_err_t ulog_backend_unregister(ulog_backend_t backend) { rt_base_t level; RT_ASSERT(backend); RT_ASSERT(ulog.init_ok); if (backend->deinit) { backend->deinit(backend); } level = rt_hw_interrupt_disable(); rt_slist_remove(&ulog.backend_list, &backend->list); rt_hw_interrupt_enable(level); return RT_EOK; } rt_err_t ulog_backend_set_filter(ulog_backend_t backend, ulog_backend_filter_t filter) { rt_base_t level; RT_ASSERT(backend); level = rt_hw_interrupt_disable(); backend->filter = filter; rt_hw_interrupt_enable(level); return RT_EOK; } ulog_backend_t ulog_backend_find(const char *name) { rt_base_t level; rt_slist_t *node; ulog_backend_t backend; RT_ASSERT(ulog.init_ok); level = rt_hw_interrupt_disable(); for (node = rt_slist_first(&ulog.backend_list); node; node = rt_slist_next(node)) { backend = rt_slist_entry(node, struct ulog_backend, list); if (rt_strncmp(backend->name, name, RT_NAME_MAX) == 0) { rt_hw_interrupt_enable(level); return backend; } } rt_hw_interrupt_enable(level); return RT_NULL; } #ifdef ULOG_USING_ASYNC_OUTPUT /** * asynchronous output logs to all backends * * @note you must call this function when ULOG_ASYNC_OUTPUT_BY_THREAD is disable */ void ulog_async_output(void) { rt_rbb_blk_t log_blk; ulog_frame_t log_frame; if (!ulog.async_enabled) { return; } while ((log_blk = rt_rbb_blk_get(ulog.async_rbb)) != RT_NULL) { log_frame = (ulog_frame_t) log_blk->buf; if (log_frame->magic == ULOG_FRAME_MAGIC) { /* output to all backends */ ulog_output_to_all_backend(log_frame->level, log_frame->tag, log_frame->is_raw, log_frame->log, log_frame->log_len); } rt_rbb_blk_free(ulog.async_rbb, log_blk); } /* output the log_raw format log */ if (ulog.async_rb) { rt_size_t log_len = rt_ringbuffer_data_len(ulog.async_rb); char *log = rt_malloc(log_len); if (log) { rt_size_t len = rt_ringbuffer_get(ulog.async_rb, (rt_uint8_t *)log, log_len); ulog_output_to_all_backend(LOG_LVL_DBG, RT_NULL, RT_TRUE, log, len); rt_free(log); } } } /** * enable or disable asynchronous output mode * the log will be output directly when mode is disabled * * @param enabled RT_TRUE: enabled, RT_FALSE: disabled */ void ulog_async_output_enabled(rt_bool_t enabled) { ulog.async_enabled = enabled; } /** * waiting for get asynchronous output log * * @param time the waiting time */ void ulog_async_waiting_log(rt_int32_t time) { rt_sem_control(&ulog.async_notice, RT_IPC_CMD_RESET, RT_NULL); rt_sem_take(&ulog.async_notice, time); } static void async_output_thread_entry(void *param) { ulog_async_output(); while (1) { ulog_async_waiting_log(RT_WAITING_FOREVER); ulog_async_output(); } } #endif /* ULOG_USING_ASYNC_OUTPUT */ /** * flush all backends's log */ void ulog_flush(void) { rt_slist_t *node; ulog_backend_t backend; if (!ulog.init_ok) return; #ifdef ULOG_USING_ASYNC_OUTPUT ulog_async_output(); #endif /* flush all backends */ for (node = rt_slist_first(&ulog.backend_list); node; node = rt_slist_next(node)) { backend = rt_slist_entry(node, struct ulog_backend, list); if (backend->flush) { backend->flush(backend); } } } int ulog_init(void) { if (ulog.init_ok) return 0; rt_mutex_init(&ulog.output_locker, "ulog", RT_IPC_FLAG_PRIO); ulog.output_lock_enabled = RT_TRUE; rt_slist_init(&ulog.backend_list); #ifdef ULOG_USING_FILTER rt_slist_init(ulog_tag_lvl_list_get()); #endif #ifdef ULOG_USING_ASYNC_OUTPUT RT_ASSERT(ULOG_ASYNC_OUTPUT_STORE_LINES >= 2); ulog.async_enabled = RT_TRUE; /* async output ring block buffer */ ulog.async_rbb = rt_rbb_create(RT_ALIGN(ULOG_ASYNC_OUTPUT_BUF_SIZE, RT_ALIGN_SIZE), ULOG_ASYNC_OUTPUT_STORE_LINES); if (ulog.async_rbb == RT_NULL) { rt_kprintf("Error: ulog init failed! No memory for async rbb.\n"); rt_mutex_detach(&ulog.output_locker); return -RT_ENOMEM; } rt_sem_init(&ulog.async_notice, "ulog", 0, RT_IPC_FLAG_FIFO); #endif /* ULOG_USING_ASYNC_OUTPUT */ #ifdef ULOG_USING_FILTER ulog_global_filter_lvl_set(LOG_FILTER_LVL_ALL); #endif ulog.init_ok = RT_TRUE; return 0; } INIT_BOARD_EXPORT(ulog_init); #ifdef ULOG_USING_ASYNC_OUTPUT int ulog_async_init(void) { if (ulog.async_th == RT_NULL) { /* async output thread */ ulog.async_th = rt_thread_create("ulog_async", async_output_thread_entry, &ulog, ULOG_ASYNC_OUTPUT_THREAD_STACK, ULOG_ASYNC_OUTPUT_THREAD_PRIORITY, 20); if (ulog.async_th == RT_NULL) { rt_kprintf("Error: ulog init failed! No memory for async output thread.\n"); return -RT_ENOMEM; } /* async output thread startup */ rt_thread_startup(ulog.async_th); } return 0; } INIT_PREV_EXPORT(ulog_async_init); #endif /* ULOG_USING_ASYNC_OUTPUT */ void ulog_deinit(void) { rt_slist_t *node; ulog_backend_t backend; if (!ulog.init_ok) return; /* deinit all backends */ for (node = rt_slist_first(&ulog.backend_list); node; node = rt_slist_next(node)) { backend = rt_slist_entry(node, struct ulog_backend, list); if (backend->deinit) { backend->deinit(backend); } } #ifdef ULOG_USING_FILTER /* deinit tag's level filter */ { ulog_tag_lvl_filter_t tag_lvl; for (node = rt_slist_first(ulog_tag_lvl_list_get()); node; node = rt_slist_next(node)) { tag_lvl = rt_slist_entry(node, struct ulog_tag_lvl_filter, list); rt_free(tag_lvl); } } #endif /* ULOG_USING_FILTER */ rt_mutex_detach(&ulog.output_locker); #ifdef ULOG_USING_ASYNC_OUTPUT rt_rbb_destroy(ulog.async_rbb); rt_thread_delete(ulog.async_th); if (ulog.async_rb) rt_ringbuffer_destroy(ulog.async_rb); #endif ulog.init_ok = RT_FALSE; } #endif /* RT_USING_ULOG */