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mirror of https://gitlab.nic.cz/labs/bird.git synced 2024-11-09 12:48:43 +00:00
bird/nest/cli.c
Maria Matejka 08ff0af898 Additional CLI sockets may now be restricted
This allows to have one main socket for the heavy operations
very restricted just for the appropriate users, whereas the
looking glass socket may be more open.

Implemented an idea originally submitted and requested by Akamai.
2024-06-27 04:14:39 +02:00

436 lines
10 KiB
C

/*
* BIRD Internet Routing Daemon -- Command-Line Interface
*
* (c) 1999--2000 Martin Mares <mj@ucw.cz>
*
* Can be freely distributed and used under the terms of the GNU GPL.
*/
/**
* DOC: Command line interface
*
* This module takes care of the BIRD's command-line interface (CLI).
* The CLI exists to provide a way to control BIRD remotely and to inspect
* its status. It uses a very simple textual protocol over a stream
* connection provided by the platform dependent code (on UNIX systems,
* it's a UNIX domain socket).
*
* Each session of the CLI consists of a sequence of request and replies,
* slightly resembling the FTP and SMTP protocols.
* Requests are commands encoded as a single line of text, replies are
* sequences of lines starting with a four-digit code followed by either
* a space (if it's the last line of the reply) or a minus sign (when the
* reply is going to continue with the next line), the rest of the line
* contains a textual message semantics of which depends on the numeric
* code. If a reply line has the same code as the previous one and it's
* a continuation line, the whole prefix can be replaced by a single
* white space character.
*
* Reply codes starting with 0 stand for `action successfully completed' messages,
* 1 means `table entry', 8 `runtime error' and 9 `syntax error'.
*
* Each CLI session is internally represented by a &cli structure and a
* resource pool containing all resources associated with the connection,
* so that it can be easily freed whenever the connection gets closed, not depending
* on the current state of command processing.
*
* The CLI commands are declared as a part of the configuration grammar
* by using the |CF_CLI| macro. When a command is received, it is processed
* by the same lexical analyzer and parser as used for the configuration, but
* it's switched to a special mode by prepending a fake token to the text,
* so that it uses only the CLI command rules. Then the parser invokes
* an execution routine corresponding to the command, which either constructs
* the whole reply and returns it back or (in case it expects the reply will be long)
* it prints a partial reply and asks the CLI module (using the @cont hook)
* to call it again when the output is transferred to the user.
*
* The @this_cli variable points to a &cli structure of the session being
* currently parsed, but it's of course available only in command handlers
* not entered using the @cont hook.
*
* TX buffer management works as follows: At cli.tx_buf there is a
* list of TX buffers (struct cli_out), cli.tx_write is the buffer
* currently used by the producer (cli_printf(), cli_alloc_out()) and
* cli.tx_pos is the buffer currently used by the consumer
* (cli_write(), in system dependent code). The producer uses
* cli_out.wpos ptr as the current write position and the consumer
* uses cli_out.outpos ptr as the current read position. When the
* producer produces something, it calls cli_write_trigger(). If there
* is not enough space in the current buffer, the producer allocates
* the new one. When the consumer processes everything in the buffer
* queue, it calls cli_written(), tha frees all buffers (except the
* first one) and schedules cli.event .
*
*/
#include "nest/bird.h"
#include "nest/cli.h"
#include "conf/conf.h"
#include "lib/string.h"
pool *cli_pool;
static byte *
cli_alloc_out(cli *c, int size)
{
struct cli_out *o;
if (!(o = c->tx_write) || o->wpos + size > o->end)
{
if (!o && c->tx_buf)
o = c->tx_buf;
else
{
o = mb_alloc(c->pool, sizeof(struct cli_out) + CLI_TX_BUF_SIZE);
if (c->tx_write)
c->tx_write->next = o;
else
c->tx_buf = o;
o->wpos = o->outpos = o->buf;
o->end = o->buf + CLI_TX_BUF_SIZE;
}
c->tx_write = o;
if (!c->tx_pos)
c->tx_pos = o;
o->next = NULL;
}
o->wpos += size;
return o->wpos - size;
}
/**
* cli_printf - send reply to a CLI connection
* @c: CLI connection
* @code: numeric code of the reply, negative for continuation lines
* @msg: a printf()-like formatting string.
*
* This function send a single line of reply to a given CLI connection.
* In works in all aspects like bsprintf() except that it automatically
* prepends the reply line prefix.
*
* Please note that if the connection can be already busy sending some
* data in which case cli_printf() stores the output to a temporary buffer,
* so please avoid sending a large batch of replies without waiting
* for the buffers to be flushed.
*
* If you want to write to the current CLI output, you can use the cli_msg()
* macro instead.
*/
void
cli_printf(cli *c, int code, char *msg, ...)
{
va_list args;
byte buf[CLI_LINE_SIZE];
int cd = code;
int errcode;
int size, cnt;
if (cd < 0)
{
cd = -cd;
if (cd == c->last_reply)
size = bsprintf(buf, " ");
else
size = bsprintf(buf, "%04d-", cd);
errcode = -8000;
}
else if (cd == CLI_ASYNC_CODE)
{
size = 1; buf[0] = '+';
errcode = cd;
}
else
{
size = bsprintf(buf, "%04d ", cd);
errcode = 8000;
cd = 0; /* Final message - no more continuation lines */
}
c->last_reply = cd;
va_start(args, msg);
cnt = bvsnprintf(buf+size, sizeof(buf)-size-1, msg, args);
va_end(args);
if (cnt < 0)
{
cli_printf(c, errcode, "<line overflow>");
return;
}
size += cnt;
buf[size++] = '\n';
memcpy(cli_alloc_out(c, size), buf, size);
}
static void
cli_copy_message(cli *c)
{
byte *p, *q;
uint cnt = 2;
if (c->ring_overflow)
{
byte buf[64];
int n = bsprintf(buf, "<%d messages lost>\n", c->ring_overflow);
c->ring_overflow = 0;
memcpy(cli_alloc_out(c, n), buf, n);
}
p = c->ring_read;
while (*p)
{
cnt++;
p++;
if (p == c->ring_end)
p = c->ring_buf;
ASSERT(p != c->ring_write);
}
c->async_msg_size += cnt;
q = cli_alloc_out(c, cnt);
*q++ = '+';
p = c->ring_read;
do
{
*q = *p++;
if (p == c->ring_end)
p = c->ring_buf;
}
while (*q++);
c->ring_read = p;
q[-1] = '\n';
}
static void
cli_hello(cli *c)
{
cli_printf(c, 1, "BIRD " BIRD_VERSION " ready.");
c->cont = NULL;
}
static void
cli_free_out(cli *c)
{
struct cli_out *o, *p;
if (o = c->tx_buf)
{
o->wpos = o->outpos = o->buf;
while (p = o->next)
{
o->next = p->next;
mb_free(p);
}
}
c->tx_write = c->tx_pos = NULL;
c->async_msg_size = 0;
}
void
cli_written(cli *c)
{
cli_free_out(c);
ev_schedule(c->event);
}
static byte *cli_rh_pos;
static uint cli_rh_len;
static int cli_rh_trick_flag;
struct cli *this_cli;
static int
cli_cmd_read_hook(byte *buf, uint max, UNUSED int fd)
{
if (!cli_rh_trick_flag)
{
cli_rh_trick_flag = 1;
buf[0] = '!';
return 1;
}
if (max > cli_rh_len)
max = cli_rh_len;
memcpy(buf, cli_rh_pos, max);
cli_rh_pos += max;
cli_rh_len -= max;
return max;
}
static void
cli_command(struct cli *c)
{
struct config f;
int res;
if (config->cli_debug > 1)
log(L_TRACE "CLI: %s", c->rx_buf);
bzero(&f, sizeof(f));
f.mem = c->parser_pool;
f.pool = rp_new(c->pool, "Config");
init_list(&f.symbols);
cf_read_hook = cli_cmd_read_hook;
cli_rh_pos = c->rx_buf;
cli_rh_len = strlen(c->rx_buf);
cli_rh_trick_flag = 0;
this_cli = c;
lp_flush(c->parser_pool);
res = cli_parse(&f);
if (!res)
cli_printf(c, 9001, f.err_msg);
config_free(&f);
}
static void
cli_event(void *data)
{
cli *c = data;
int err;
while (c->ring_read != c->ring_write &&
c->async_msg_size < CLI_MAX_ASYNC_QUEUE)
cli_copy_message(c);
if (c->tx_pos)
;
else if (c->cont)
c->cont(c);
else
{
err = cli_get_command(c);
if (!err)
return;
if (err < 0)
cli_printf(c, 9000, "Command too long");
else
cli_command(c);
}
cli_write_trigger(c);
}
cli *
cli_new(void *priv, struct cli_config *cf)
{
pool *p = rp_new(cli_pool, "CLI");
cli *c = mb_alloc(p, sizeof(cli));
bzero(c, sizeof(cli));
c->pool = p;
c->priv = priv;
c->event = ev_new(p);
c->event->hook = cli_event;
c->event->data = c;
c->cont = cli_hello;
c->parser_pool = lp_new_default(c->pool);
c->show_pool = lp_new_default(c->pool);
c->rx_buf = mb_alloc(c->pool, CLI_RX_BUF_SIZE);
if (cf->restricted)
c->restricted = 1;
ev_schedule(c->event);
return c;
}
void
cli_kick(cli *c)
{
if (!c->cont && !c->tx_pos)
ev_schedule(c->event);
}
static list cli_log_hooks;
static int cli_log_inited;
void
cli_set_log_echo(cli *c, uint mask, uint size)
{
if (c->ring_buf)
{
mb_free(c->ring_buf);
c->ring_buf = c->ring_end = c->ring_read = c->ring_write = NULL;
rem_node(&c->n);
}
c->log_mask = mask;
if (mask && size)
{
c->ring_buf = mb_alloc(c->pool, size);
c->ring_end = c->ring_buf + size;
c->ring_read = c->ring_write = c->ring_buf;
add_tail(&cli_log_hooks, &c->n);
c->log_threshold = size / 8;
}
c->ring_overflow = 0;
}
void
cli_echo(uint class, byte *msg)
{
unsigned len, free, i, l;
cli *c;
byte *m;
if (!cli_log_inited || EMPTY_LIST(cli_log_hooks))
return;
len = strlen(msg) + 1;
WALK_LIST(c, cli_log_hooks)
{
if (!(c->log_mask & (1 << class)))
continue;
if (c->ring_read <= c->ring_write)
free = (c->ring_end - c->ring_buf) - (c->ring_write - c->ring_read + 1);
else
free = c->ring_read - c->ring_write - 1;
if ((len > free) ||
(free < c->log_threshold && class < (unsigned) L_INFO[0]))
{
c->ring_overflow++;
continue;
}
if (c->ring_read == c->ring_write)
ev_schedule(c->event);
m = msg;
l = len;
while (l)
{
if (c->ring_read <= c->ring_write)
i = c->ring_end - c->ring_write;
else
i = c->ring_read - c->ring_write;
if (i > l)
i = l;
memcpy(c->ring_write, m, i);
m += i;
l -= i;
c->ring_write += i;
if (c->ring_write == c->ring_end)
c->ring_write = c->ring_buf;
}
}
}
/* Hack for scheduled undo notification */
extern cli *cmd_reconfig_stored_cli;
void
cli_free(cli *c)
{
cli_set_log_echo(c, 0, 0);
if (c->cleanup)
c->cleanup(c);
if (c == cmd_reconfig_stored_cli)
cmd_reconfig_stored_cli = NULL;
rfree(c->pool);
}
/**
* cli_init - initialize the CLI module
*
* This function is called during BIRD startup to initialize
* the internal data structures of the CLI module.
*/
void
cli_init(void)
{
cli_pool = rp_new(&root_pool, "CLI");
init_list(&cli_log_hooks);
cli_log_inited = 1;
}