incubator-nuttx/drivers/syslog
Xiang Xiao f1ed349dd9 sched/clock: Remove CLOCK_MONOTONIC option from Kconfig
here is the reason:
1.clock_systime_timespec(core function) always exist regardless the setting
2.CLOCK_MONOTONIC is a foundamental clock type required by many places

Signed-off-by: Xiang Xiao <xiaoxiang@xiaomi.com>
2022-02-23 01:21:26 +08:00
..
Kconfig drivers/syslog: Implement RTT based log channel 2022-02-01 11:26:46 +01:00
Make.defs drivers/syslog: Remove emergstream implementation and caller 2021-05-18 09:26:28 -03:00
README.txt SYSLOG channel add functions return handle to the channel. 2021-06-03 08:36:15 -05:00
ramlog.c Correct the code alignment 2022-02-01 21:22:21 -03:00
syslog.h libc: Move syslog_stream from nuttx/streams.h to drivers/syslog/syslog.h 2021-12-14 00:51:59 -06:00
syslog_channel.c drivers/syslog: Implement RTT based log channel 2022-02-01 11:26:46 +01:00
syslog_chardev.c change /dev/syslog & /dev/ramlog for unix standard 2021-11-24 05:19:46 -06:00
syslog_console.c file_operations: get back C89 compatible initializer 2022-01-11 02:14:00 +08:00
syslog_consolechannel.c syslog: Fix in file channel initialization. 2022-01-13 19:16:10 +01:00
syslog_devchannel.c syslog: Fix in file channel initialization. 2022-01-13 19:16:10 +01:00
syslog_device.c drivers/syslog/syslog_device: fix flushing data when end of line is detected 2022-02-05 03:10:31 +08:00
syslog_filechannel.c syslog: Fix in file channel initialization. 2022-01-13 19:16:10 +01:00
syslog_flush.c syslog: Added multi device support in syslog_device. 2021-04-06 07:32:23 -05:00
syslog_force.c syslog: Added multi device support in syslog_device. 2021-04-06 07:32:23 -05:00
syslog_initialize.c SYSLOG channel add functions return handle to the channel. 2021-06-03 08:36:15 -05:00
syslog_intbuffer.c syslog/intbuf: output log when syslog interrupt buffer is full 2021-07-10 11:08:59 -07:00
syslog_putc.c syslog: Added multi device support in syslog_device. 2021-04-06 07:32:23 -05:00
syslog_rpmsg.c syslog: Include nuttx/syslog/syslog.h in include/nuttx/syslog/syslog_rpmsg.h 2022-01-31 13:41:56 +01:00
syslog_rpmsg.h Fix nxstyle warning 2020-08-22 17:37:21 -06:00
syslog_rpmsg_server.c syslog: Include nuttx/syslog/syslog.h in include/nuttx/syslog/syslog_rpmsg.h 2022-01-31 13:41:56 +01:00
syslog_stream.c libc: Move syslog_stream from nuttx/streams.h to drivers/syslog/syslog.h 2021-12-14 00:51:59 -06:00
syslog_write.c Don't include assert.h from public header file 2021-06-03 08:36:03 -07:00
vsyslog.c sched/clock: Remove CLOCK_MONOTONIC option from Kconfig 2022-02-23 01:21:26 +08:00

README.txt

drivers/syslog README File
==========================

SYSLOG Interfaces
=================

  Standard SYSLOG Interfaces
  --------------------------
  The NuttX SYSLOG is an architecture for getting debug and status
  information from the system.  The syslogging interfaces are defined in the
  header file include/syslog.h.  The primary interface to SYSLOG sub-system
  is the function syslog() and, to a lesser extent, its companion vsyslog():

  syslog() and vsyslog()
  ----------------------
  Prototypes:

    int syslog(int priority, FAR const IPTR char *format, ...);
    void vsyslog(int priority, FAR const IPTR char *src, va_list ap);

  Description:

    syslog() generates a log message. The priority argument is formed by
    ORing the facility and the level values (see include/syslog.h). The
    remaining arguments are a format, as in printf and any arguments to the
    format.

    The NuttX implementation does not support any special formatting
    characters beyond those supported by printf.

    The function vsyslog() performs the same task as syslog() with the
    difference that it takes a set of arguments which have been obtained
    using the stdarg variable argument list macros.

  setlogmask()
  ------------
  The additional setlogmask() interface can use use to filter SYSLOG output:

  Prototypes:

    int setlogmask(int mask);

  Description:

    The setlogmask() function sets the logmask and returns the previous
    mask. If the mask argument is 0, the current logmask is not modified.

    The SYSLOG priorities are: LOG_EMERG, LOG_ALERT, LOG_CRIT, LOG_ERR,
    LOG_WARNING, LOG_NOTICE, LOG_INFO, and LOG_DEBUG.  The bit corresponding
    to a priority p is LOG_MASK(p); LOG_UPTO(p) provides the mask of all
    priorities in the above list up to and including p.

    Per OpenGroup.org "If the maskpri argument is 0, the current log mask
    is not modified."  In this implementation, the value zero is permitted
    in order to disable all syslog levels.

    REVISIT: Per POSIX the syslog mask should be a per-process value but in
    NuttX, the scope of the mask is dependent on the nature of the build:

    * Flat Build:  There is one, global SYSLOG mask that controls all output.
      Protected Build:  There are two SYSLOG masks.  One within the kernel
      that controls only kernel output.  And one in user-space that controls
      only user SYSLOG output.
    * Kernel Build:  The kernel build is compliant with the POSIX requirement:
      There will be one mask for for each user process, controlling the
      SYSLOG output only form that process.  There will be a separate mask
      accessible only in the kernel code to control kernel SYSLOG output.
     *

  These are all standard interfaces as defined at http://pubs.opengroup.org/onlinepubs/009695399/functions/closelog.html

  Debug Interfaces
  ----------------
  In NuttX, syslog output is really synonymous to debug output and,
  therefore, the debugging interface macros defined in the header file
  include/debug.h are also syslogging interfaces.  Those macros are simply
  wrappers around syslog().  The debugging interfaces differ from the syslog
  interfaces in that:

    * They do not take a priority parameter; the priority is inherent in the
      debug macro name.
    * They decorate the output stream with information such as the file name
    * They can each be disabled via configuration options.

  Each debug macro has a base name that represents the priority and a prefix
  that represents the sub-system.  Each macro is individually initialized by
  both priority and sub-system.  For example, uerr() is the macro used for
  error level messages from the USB subsystem and is enabled with
  CONFIG_DEBUG_USB_ERROR.

  The base debug macro names, their priority, and configuration variable are
  summarized below:

    * info().  The info() macro is the lowest priority (LOG_INFO) and is
      intended to provide general information about the flow of program
      execution so that you can get an overview of the behavior of the
      program.  info() is often very chatty and voluminous and usually more
      information than you may want to see.  The info() macro is controlled
      via CONFIG_DEBUG_subsystem_INFO
    * warn().  The warn() macro has medium priority (LOG_WARN) and is
      controlled by CONFIG_DEBUG_subsystem_WARN.  The warn() is intended to
      note exceptional or unexpected conditions that meigh be potential
      errors or, perhaps, minor errors that easily recovered.
    * err().  This is a high priority debug macro (LOG_ERROR) and controlled
      by CONFIG_DEBUG_subsystem_ERROR.  The err() is reserved to indicate
      important error conditions.
    * alert(). The highest priority debug macro (LOG_EMERG) and is
      controlled by CONFIG_DEBUG_ALERT.  The alert() macro is reserved for
      use solely by assertion and crash handling logic.  It also differs
      from the other macros in that it cannot be enabled or disabled per
      subsystem.

SYSLOG Channels
===============

  SYSLOG Channel Interfaces
  -------------------------
  In the NuttX SYSLOG implementation, the underlying device logic the
  supports the SYSLOG output is referred to as a SYSLOG channel.  Each
  SYSLOG channel is represented by an interface defined in
  include/nuttx/syslog/syslog.h:

    /* SYSLOG I/O redirection methods */

    typedef CODE ssize_t (*syslog_write_t)(FAR struct syslog_channel_s *channel,
                                       FAR const char *buf, size_t buflen);
    typedef CODE int (*syslog_putc_t)(FAR struct syslog_channel_s *channel,
                                  int ch);
    typedef CODE int (*syslog_flush_t)(FAR struct syslog_channel_s *channel);

    /* SYSLOG device operations */

    struct syslog_channel_ops_s
    {
      syslog_putc_t  sc_putc;   /* Normal buffered output */
      syslog_putc_t  sc_force;  /* Low-level output for interrupt handlers */
      syslog_flush_t sc_flush;  /* Flush buffered output (on crash) */
      syslog_write_t sc_write;  /* Write multiple bytes */
    };

    /* This structure provides the interface to a SYSLOG channel */

    struct syslog_channel_s
    {
      /* Channel operations */

      FAR const struct syslog_channel_ops_s *sc_ops;

      /* Implementation specific logic may follow */
    };

  The channel interface is instantiated by calling syslog_channel():

  syslog_channel()
  ----------------
  Prototype:

    int syslog_channel(FAR const struct syslog_channel_s *channel);

  Description:

    Configure the SYSLOGging function to use the provided channel to
    generate SYSLOG output.

    syslog_channel() is a non-standard, internal OS interface and is not
    available to applications.  It may be called numerous times as
    necessary to change channel interfaces.

  Input Parameters:

     * channel - Provides the interface to the channel to be used.

  Returned Value:

    Zero (OK) is returned on success.  A negated errno value is returned
    on any failure.

  SYSLOG Channel Initialization
  -----------------------------
  The initial, default SYSLOG channel is established with statically
  initialized global variables so that some level of SYSLOG output may be
  available immediately upon reset.  This initialized data is in the file
  drivers/syslog/syslog_channel.c.  The initial SYSLOG capability is
  determined by the selected SYSLOG channel:

    * In-Memory Buffer (RAMLOG).  Full SYSLOG capability as available at
      reset.
    * Serial Console.  If the serial implementation provides the low-level
      character output function up_putc(), then that low level serial output
      is available as soon as the serial device has been configured.
    * For all other SYSLOG channels, all SYSLOG output goes to the bit-
      bucket until the SYSLOG channel device has been initialized.

  The syslog channel device is initialized when the bring-up logic calls
  syslog_initialize():

  syslog_initialize()
  -------------------
  Prototype:

    #ifndef CONFIG_ARCH_SYSLOG
    int syslog_initialize(void);
    #else
    #  define syslog_initialize()
    #endif

  Description:

    On power up, the SYSLOG facility is non-existent or limited to very
    low-level output.  This function is called later in the initialization
    sequence after full driver support has been initialized.  It installs
    the configured SYSLOG drivers and enables full SYSLOGing capability.

    This function performs these basic operations:

    * Initialize the SYSLOG device
    * Call syslog_channel() to begin using that device.
    * If CONFIG_ARCH_SYSLOG is selected, then the architecture-specific
      logic will provide its own SYSLOG device initialize which must include
      as a minimum a call to syslog_channel() to use the device.

  Returned Value:
    Zero (OK) is returned on success; a negated errno value is returned on
    any failure.

  Different types of SYSLOG devices have different OS initialization
  requirements.  Some are available immediately at reset, some are available
  after some basic OS initialization, and some only after OS is fully
  initialized.

  There are other types of SYSLOG channel devices that may require even
  further initialization.  For example, the file SYSLOG channel (described
  below) cannot be initialized until the necessary file systems have been
  mounted.

  Interrupt Level SYSLOG Output
  -----------------------------
  As a general statement, SYSLOG output only supports //normal// output from
  NuttX tasks.  However, for debugging purposes, it is also useful to get
  SYSLOG output from interrupt level logic.  In an embedded system, that is
  often where the most critical operations are performed.

  There are three conditions under which SYSLOG output generated from
  interrupt level processing can a included the SYSLOG output stream:

  1. Low-Level Serial Output
  --------------------------
  If you are using a SYSLOG console channel (CONFIG_SYSLOG_CONSOLE) and if
  the underlying architecture supports the low-level up_putc() interface
  (CONFIG_ARCH_LOWPUTC), then the SYSLOG logic will direct the output to
  up_putc() which is capable of generating the serial output within the
  context of an interrupt handler.

  There are a few issues in doing this however:

    * up_putc() is able to generate debug output in any context because it
      disables serial interrupts and polls the hardware directly.  These
      polls may take many milliseconds and during that time, all interrupts
      are disable within the interrupt handler.  This, of course, interferes
      with the real-time behavior of the RTOS.
    * The output generated by up_putc() is immediate and in real-time.  The
      normal SYSLOG output, on the other hand, is buffered in the serial
      driver and may be delayed with respect to the immediate output by many
      lines.  Therefore, the interrupt level SYSLOG output provided through
      up_putc() is grossly out of synchronization with other debug output

  2. In-Memory Buffering
  ----------------------
  If the RAMLOG SYSLOG channel is supported, then all SYSLOG output is
  buffered in memory.  Interrupt level SYSLOG output is no different than
  normal SYSLOG output in this case.

  3. Serialization Buffer
  -----------------------
  A final option is the use of an "interrupt buffer" to buffer the
  interrupt level SYSLOG output.  In this case:

    * SYSLOG output generated from interrupt level process in not sent to
      the SYSLOG channel immediately.  Rather, it is buffered in the
      interrupt serialization buffer.
    * Later, when the next normal syslog output is generated, it will first
      empty the content of the interrupt buffer to the SYSLOG device in the
      proper context.  It will then be followed by the normal syslog output.
      In this case, the interrupt level SYSLOG output will interrupt the
      normal output stream and the interrupt level SYSLOG output will be
      inserted into the correct position in the SYSLOG output when the next
      normal SYSLOG output is generated.

  The SYSLOG interrupt buffer is enabled with CONFIG_SYSLOG_INTBUFFER.  When
  the interrupt buffer is enabled, you must also provide the size of the
  interrupt buffer with CONFIG_SYSLOG_INTBUFSIZE.

SYSLOG Channel Options
======================

  SYSLOG Console Device
  ---------------------
  The typical SYSLOG device is the system console.  If you are using a
  serial console, for example, then the SYSLOG output will appear on that
  serial port.

  This SYSLOG channel is automatically selected by syslog_initialize() in
  the LATE initialization phase based on configuration options.  The
  configuration options that affect this channel selection include:

    * CONFIG_DEV_CONSOLE.  This setting indicates that the system supports a
      console device, i.e., that the character device /dev/console exists.
    * CONFIG_SERIAL_CONSOLE.  This configuration option is automatically
      selected when a UART or USART is configured as the system console.
      There is no user selection.
    * CONFIG_SYSLOG_CONSOLE.  This configuration option is manually selected
      from the SYSLOG menu.  This is the option that actually enables the
      SYSLOG console device.  It depends on CONFIG_DEV_CONSOLE.
    * CONFIG_ARCH_LOWPUTC.  This is an indication from the architecture
      configuration that the platform supports the up_putc() interface.
      up_putc() is a very low level UART interface that can even be used from
      interrupt handling.

  Interrupt level SYSLOG output will be lost unless:  (1) the interrupt buffer
  is enabled to support serialization, or (2) a serial console is used and
  up_putc() is supported.

  NOTE: The console channel uses the fixed character device at /dev/console.
  The console channel is not synonymous with stdout (or file descriptor 1).
  stdout is the current output from a task when, say, printf() if used.
  Initially, stdout does, indeed, use the /dev/console device.  However,
  stdout may subsequently be redirected to some other device or file.  This
  is always the case, for example, when a transient device is used for a
  console -- such as a USB console or a Telnet console.  The SYSLOG channel
  is not redirected as stdout is; the SYSLOG channel will stayed fixed (unless
  it is explicitly changed via syslog_channel()).

  References: drivers/syslog/syslog_consolechannel.c and
  drivers/syslog/syslog_device.c

  SYSLOG Character Device
  -----------------------
  The system console device, /dev/console, is a character driver with some
  special properties.  However, any character driver may be used as the
  SYSLOG output channel.  For example, suppose you have a serial console on
  /dev/ttyS0 and you want SYSLOG output on /dev/ttyS1.  Or suppose you
  support only a Telnet console but want to capture debug output
  /dev/ttyS0.

  This SYSLOG device channel is selected with CONFIG_SYSLOG_CHAR and has no
  other dependencies.  Differences from the SYSLOG console channel include:

    * CONFIG_SYSLOG_DEVPATH.  This configuration option string must be set
      provide the full path to the character device to be used.
    * The forced SYSLOG output always goes to the bit-bucket.  This means
      that interrupt level SYSLOG output will be lost unless the interrupt
      buffer is enabled to support serialization.

  References: drivers/syslog/syslog_devchannel.c and
  drivers/syslog/syslog_device.c

  SYSLOG File Device
  ------------------
  Files can also be used as the sink for SYSLOG output.  There is, however,
  a very fundamental difference in using a file as opposed the system
  console, a RAM buffer, or character device:  You must first mount the
  file system that supports the SYSLOG file.  That difference means that
  the file SYSLOG channel cannot be supported during the boot-up phase but
  can be instantiated later when board level logic configures the application
  environment, including mounting of the file systems.

  The interface syslog_file_channel() is used to configure the SYSLOG file
  channel:

  syslog_file_channel()
  ---------------------
  Prototype:

    #ifdef CONFIG_SYSLOG_FILE
    FAR struct syslog_channel_s *syslog_file_channel(FAR const char *devpath);
    #endif

  Description:

    Configure to use a file in a mounted file system at 'devpath' as the
    SYSLOG channel.

    This tiny function is simply a wrapper around syslog_dev_initialize()
    and syslog_channel().  It calls syslog_dev_initialize() to configure
    the character file at 'devpath' and then calls syslog_channel() to use
    that device as the SYSLOG output channel.

    File SYSLOG channels differ from other SYSLOG channels in that they
    cannot be established until after fully booting and mounting the target
    file system.  This function would need to be called from board-specific
    bring-up logic AFTER mounting the file system containing 'devpath'.

    SYSLOG data generated prior to calling syslog_file_channel will, of
    course, not be included in the file.

    NOTE interrupt level SYSLOG output will be lost in this case unless
    the interrupt buffer is used.

  Input Parameters:

    * devpath - The full path to the file to be used for SYSLOG output.
      This may be an existing file or not.  If the file exists,
      syslog_file_channel() will append new SYSLOG data to the end of the
      file.  If it does not, then syslog_file_channel() will create the
      file.

  Returned Value:

    A pointer to the new SYSLOG channel; NULL is returned on any failure.

  References: drivers/syslog/syslog_filechannel.c,
  drivers/syslog/syslog_device.c, and include/nuttx/syslog/syslog.h.

  SYSLOG RAMLOG Device
  --------------------
  The RAMLOG is a standalone feature that can be used to buffer any
  character data in memory.  There are, however, special configurations
  that can be used to configure the RAMLOG as a SYSLOG channel.  The RAMLOG
  functionality is described in a more general way in the following
  paragraphs.

RAM Logging Device
==================

  The RAM logging driver is a driver that was intended to support debugging
  output (SYSLOG) when the normal serial output is not available.  For
  example, if you are using a Telnet or USB serial console, the debug output
  will get lost -- or worse.  For example, what if you want to debug the
  network over Telnet?

  The RAM logging driver can also accept debug output data from interrupt
  handler with no special serialization buffering.  As an added benefit, the
  RAM logging driver is much less invasive.  Since no actual I/O is performed
  with the debug output is generated, the RAM logger tends to be much faster
  and will interfere much less when used with time critical drivers.

  The RAM logging driver is similar to a pipe in that it saves the debugging
  output in a circular buffer in RAM.  It differs from a pipe in numerous
  details as needed to support logging.

  This driver is built when CONFIG_RAMLOG is defined in the NuttX
  configuration.

  dmesg
  -----
  When the RAMLOG (with SYSLOG) is enabled, a new NuttShell (NSH) command
  will appear:  dmesg.  The dmsg command will dump the contents of the
  circular buffer to the console (and also clear the circular buffer).

  RAMLOG Configuration options
  ----------------------------

    * CONFIG_RAMLOG - Enables the RAM logging feature
    * CONFIG_RAMLOG_SYSLOG - Use the RAM logging device for the syslogging
      interface.  If this feature is enabled, then all debug output (only)
      will be re-directed to the circular buffer in RAM.  This RAM log can
      be viewed from NSH using the 'dmesg' command.  NOTE:  Unlike the
      limited, generic character driver SYSLOG device, the RAMLOG *can* be
      used to capture debug output from interrupt level handlers.
    * CONFIG_RAMLOG_NPOLLWAITERS - The number of threads than can be waiting
      for this driver on poll().  Default: 4

  If CONFIG_RAMLOG_SYSLOG is selected, then the following must also be
  provided:

    * CONFIG_RAMLOG_BUFSIZE - The size of the circular buffer to use.
      Default: 1024 bytes.

  Other miscellaneous settings

    * CONFIG_RAMLOG_CRLF - Pre-pend a carriage return before every linefeed
      that goes into the RAM log.
    * CONFIG_RAMLOG_NONBLOCKING - Reading from the RAMLOG will never block
      if the RAMLOG is empty.  If the RAMLOG is empty, then zero is returned
      (usually interpreted as end-of-file).  If you do not define this, the
      NSH 'dmsg' command will lock up when called!  So you probably do want
      this!
    * CONFIG_RAMLOG_NPOLLWAITERS - The maximum number of threads that may be
      waiting on the poll method.