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bird/nest/config.Y

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/*
* BIRD -- Core Configuration
*
* (c) 1998--2000 Martin Mares <mj@ucw.cz>
2004-07-13 14:46:14 +00:00
* (c) 2004 Ondrej Filip <feela@network.cz>
*
* Can be freely distributed and used under the terms of the GNU GPL.
*/
CF_HDR
#include "nest/rt-dev.h"
#include "nest/password.h"
#include "nest/cmds.h"
#include "nest/mpls.h"
#include "lib/lists.h"
#include "lib/mac.h"
CF_DEFINES
static struct rtable_config *this_table;
static struct proto_config *this_proto;
static struct channel_config *this_channel;
static struct iface_patt *this_ipatt;
static struct iface_patt_node *this_ipn;
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/* static struct roa_table_config *this_roa_table; */
static list *this_p_list;
static struct password_item *this_p_item;
static int password_id;
static struct bfd_options *this_bfd_opts;
static void
iface_patt_check(void)
{
struct iface_patt_node *pn;
WALK_LIST(pn, this_ipatt->ipn_list)
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if (!pn->pattern || pn->prefix.type)
cf_error("Interface name/mask expected, not IP prefix");
}
static inline void
init_password_list(void)
{
if (!this_p_list) {
this_p_list = cfg_allocz(sizeof(list));
init_list(this_p_list);
password_id = 1;
}
}
static inline void
init_password(const void *key, uint length, uint id)
{
this_p_item = cfg_allocz(sizeof (struct password_item));
this_p_item->password = key;
this_p_item->length = length;
this_p_item->genfrom = 0;
this_p_item->gento = TIME_INFINITY;
this_p_item->accfrom = 0;
this_p_item->accto = TIME_INFINITY;
this_p_item->id = id;
this_p_item->alg = ALG_UNDEFINED;
add_tail(this_p_list, &this_p_item->n);
}
static inline void
reset_passwords(void)
{
this_p_list = NULL;
}
static inline list *
get_passwords(void)
{
list *rv = this_p_list;
this_p_list = NULL;
return rv;
}
static inline void
init_bfd_opts(struct bfd_options **opts)
{
cf_check_bfd(1);
if (! *opts)
*opts = bfd_new_options();
}
static inline void
open_bfd_opts(struct bfd_options **opts)
{
init_bfd_opts(opts);
this_bfd_opts = *opts;
}
static inline void
close_bfd_opts(void)
{
this_bfd_opts = NULL;
}
static void
proto_postconfig(void)
{
CALL(this_proto->protocol->postconfig, this_proto);
this_channel = NULL;
this_proto = NULL;
}
#define DIRECT_CFG ((struct rt_dev_config *) this_proto)
CF_DECLS
CF_KEYWORDS(ROUTER, ID, HOSTNAME, PROTOCOL, TEMPLATE, PREFERENCE, DISABLED, DEBUG, ALL, OFF, DIRECT)
CF_KEYWORDS(INTERFACE, IMPORT, EXPORT, FILTER, NONE, VRF, DEFAULT, TABLE, TABLES, STATES, ROUTES, FILTERS)
CF_KEYWORDS(IPV4, IPV6, VPN4, VPN6, ROA4, ROA6, FLOW4, FLOW6, SADR, ETH, MPLS)
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CF_KEYWORDS(RECEIVE, LIMIT, ACTION, WARN, BLOCK, RESTART, DISABLE, KEEP, FILTERED, RPKI)
CF_KEYWORDS(PASSWORD, KEY, FROM, PASSIVE, TO, ID, EVENTS, PACKETS, PROTOCOLS, CHANNELS, INTERFACES)
CF_KEYWORDS(ALGORITHM, KEYED, HMAC, MD5, SHA1, SHA256, SHA384, SHA512, BLAKE2S128, BLAKE2S256, BLAKE2B256, BLAKE2B512)
CF_KEYWORDS(PRIMARY, STATS, COUNT, FOR, IN, COMMANDS, PREEXPORT, NOEXPORT, EXPORTED, GENERATE)
CF_KEYWORDS(BGP, PASSWORDS, DESCRIPTION)
CF_KEYWORDS(RELOAD, IN, OUT, MRTDUMP, MESSAGES, RESTRICT, MEMORY, IGP_METRIC, CLASS, DSCP)
CF_KEYWORDS(TIMEFORMAT, ISO, SHORT, LONG, ROUTE, PROTOCOL, BASE, LOG, S, MS, US)
CF_KEYWORDS(GRACEFUL, RESTART, WAIT, MAX, AS)
CF_KEYWORDS(MIN, IDLE, RX, TX, INTERVAL, MULTIPLIER, PASSIVE)
CF_KEYWORDS(CHECK, LINK)
CF_KEYWORDS(SORTED, TRIE, MIN, MAX, SETTLE, TIME, GC, THRESHOLD, PERIOD)
CF_KEYWORDS(MPLS_LABEL, MPLS_POLICY, MPLS_CLASS)
/* For r_args_channel */
CF_KEYWORDS(IPV4, IPV4_MC, IPV4_MPLS, IPV6, IPV6_MC, IPV6_MPLS, IPV6_SADR, VPN4, VPN4_MC, VPN4_MPLS, VPN6, VPN6_MC, VPN6_MPLS, ROA4, ROA6, FLOW4, FLOW6, MPLS, PRI, SEC)
CF_ENUM(T_ENUM_RTS, RTS_, STATIC, INHERIT, DEVICE, STATIC_DEVICE, REDIRECT,
RIP, OSPF, OSPF_IA, OSPF_EXT1, OSPF_EXT2, BGP, PIPE, BABEL, RPKI, L3VPN,
AGGREGATED)
CF_ENUM(T_ENUM_SCOPE, SCOPE_, HOST, LINK, SITE, ORGANIZATION, UNIVERSE, UNDEFINED)
CF_ENUM(T_ENUM_RTD, RTD_, UNICAST, BLACKHOLE, UNREACHABLE, PROHIBIT)
CF_ENUM(T_ENUM_ROA, ROA_, UNKNOWN, VALID, INVALID)
CF_ENUM_PX(T_ENUM_AF, AF_, AFI_, IPV4, IPV6)
CF_ENUM(T_ENUM_MPLS_POLICY, MPLS_POLICY_, NONE, STATIC, PREFIX, AGGREGATE, VRF)
CF_ENUM(T_ENUM_NET_EVPN, NET_EVPN_, EAD, MAC, IMET, ES)
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%type <i32> idval
%type <f> imexport
%type <r> rtable
%type <s> optproto
%type <ra> r_args
%type <sd> sym_args
%type <i> proto_start echo_mask echo_size debug_mask debug_list debug_flag mrtdump_mask mrtdump_list mrtdump_flag export_mode limit_action net_type net_type_base tos password_algorithm
%type <ps> proto_patt proto_patt2
%type <cc> channel_start proto_channel
%type <cl> limit_spec
%type <net> r_args_for_val
%type <net_ptr> r_args_for
%type <t> channel_sym
%type <c> channel_arg
CF_GRAMMAR
/* Setting of router ID */
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conf: rtrid ;
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rtrid:
ROUTER ID idval ';' { new_config->router_id = $3; }
| ROUTER ID FROM iface_patt ';' { new_config->router_id_from = this_ipatt; }
;
idval:
NUM { $$ = $1; }
| '(' term ')' { $$ = cf_eval_int($2); }
| IP4 { $$ = ip4_to_u32($1); }
| CF_SYM_KNOWN {
if ($1->class == (SYM_CONSTANT | T_INT) || $1->class == (SYM_CONSTANT | T_QUAD))
$$ = SYM_VAL($1).i;
else if (($1->class == (SYM_CONSTANT | T_IP)) && ipa_is_ip4(SYM_VAL($1).ip))
$$ = ipa_to_u32(SYM_VAL($1).ip);
else
cf_error("Number or IPv4 address constant expected");
}
;
conf: hostname_override ;
hostname_override: HOSTNAME text ';' { new_config->hostname = $2; } ;
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conf: gr_opts ;
gr_opts: GRACEFUL RESTART WAIT expr ';' { new_config->gr_wait = $4; } ;
/* Network types (for tables, channels) */
net_type_base:
IPV4 { $$ = NET_IP4; }
| IPV6 { $$ = NET_IP6; }
| IPV6 SADR { $$ = NET_IP6_SADR; }
| VPN4 { $$ = NET_VPN4; }
| VPN6 { $$ = NET_VPN6; }
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| ROA4 { $$ = NET_ROA4; }
| ROA6 { $$ = NET_ROA6; }
| FLOW4{ $$ = NET_FLOW4; }
| FLOW6{ $$ = NET_FLOW6; }
| ETH { $$ = NET_ETH; }
| EVPN { $$ = NET_EVPN; }
;
net_type:
net_type_base
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| MPLS { $$ = NET_MPLS; }
;
CF_ENUM(T_ENUM_NETTYPE, NET_, IP4, IP6, VPN4, VPN6, ROA4, ROA6, FLOW4, FLOW6, IP6_SADR, ETH, MPLS, EVPN)
/* Creation of routing tables */
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conf: table ;
table: table_start table_sorted table_opt_list ;
table_start: net_type TABLE symbol {
this_table = rt_new_table($3, $1);
}
;
table_sorted:
/* empty */
| SORTED { this_table->sorted = 1; }
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;
table_opt:
SORTED bool { this_table->sorted = $2; }
| DEBUG debug_mask { this_table->debug = $2; }
| TRIE bool {
if (!net_val_match(this_table->addr_type, NB_IP | NB_VPN | NB_ROA | NB_IP6_SADR))
cf_error("Trie option not supported for %s table", net_label[this_table->addr_type]);
this_table->trie_used = $2;
}
| MIN SETTLE TIME expr_us { this_table->min_settle_time = $4; }
| MAX SETTLE TIME expr_us { this_table->max_settle_time = $4; }
| GC THRESHOLD expr { this_table->gc_threshold = $3; }
| GC PERIOD expr_us { this_table->gc_period = (uint) $3; if ($3 > 3600 S_) cf_error("GC period must be at most 3600 s"); }
;
table_opts:
/* empty */
| table_opts table_opt ';'
;
table_opt_list:
/* empty */
| '{' table_opts '}'
;
/* Definition of protocols */
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conf: proto { proto_postconfig(); } ;
proto_start:
PROTOCOL { $$ = SYM_PROTO; }
| TEMPLATE { $$ = SYM_TEMPLATE; }
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;
proto_name:
/* EMPTY */ {
struct symbol *s = cf_default_name(new_config, this_proto->protocol->template, &this_proto->protocol->name_counter);
s->class = this_proto->class;
s->proto = this_proto;
this_proto->name = s->name;
}
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| symbol {
cf_define_symbol(new_config, $1, this_proto->class, proto, this_proto);
this_proto->name = $1->name;
}
| FROM CF_SYM_KNOWN {
if (($2->class != SYM_TEMPLATE) && ($2->class != SYM_PROTO)) cf_error("Template or protocol name expected");
struct symbol *s = cf_default_name(new_config, this_proto->protocol->template, &this_proto->protocol->name_counter);
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s->class = this_proto->class;
s->proto = this_proto;
this_proto->name = s->name;
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proto_copy_config(this_proto, $2->proto);
}
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| symbol FROM CF_SYM_KNOWN {
if (($3->class != SYM_TEMPLATE) && ($3->class != SYM_PROTO)) cf_error("Template or protocol name expected");
cf_define_symbol(new_config, $1, this_proto->class, proto, this_proto);
this_proto->name = $1->name;
proto_copy_config(this_proto, $3->proto);
}
;
proto_item:
/* EMPTY */
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| DISABLED bool { this_proto->disabled = $2; }
Added protocol debugging flags (protocol.h: D_xxx), parsing of them in configuration files and commands for manipulating them. Current debug message policy: o D_STATES, D_ROUTES and D_FILTERS are handled in generic code. o Other debug flags should be handled in the protocols and whenever the flag is set, the corresponding messages should be printed using calls to log(L_TRACE, ...), each message prefixed with the name of the protocol instance. These messages should cover the whole normal operation of the protocol and should be useful for an administrator trying to understand what does the protocol behave on his network or who is attempting to diagnose network problems. If your messages don't fit to the categories I've defined, feel free to add your own ones (by adding them to protocol.h and on two places in nest/config.Y), but please try to keep the categories as general as possible (i.e., not tied to your protocol). o Internal debug messages not interesting even to an experienced user should be printed by calling DBG() which is either void or a call to debug() depending on setting of the LOCAL_DEBUG symbol at the top of your source. o Dump functions (proto->dump etc.) should call debug() to print their messages. o If you are doing any internal consistency checks, use ASSERT or bug(). o Nobody shall ever call printf() or any other stdio functions. Also please try to log any protocol errors you encounter and tag them with the appropriate message category (usually L_REMOTE or L_AUTH). Always carefully check contents of any message field you receive and verify all IP addresses you work with (by calling ipa_classify() or by using the neighbour cache if you want to check direct connectedness as well).
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| DEBUG debug_mask { this_proto->debug = $2; }
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| MRTDUMP mrtdump_mask { this_proto->mrtdump = $2; }
| ROUTER ID idval { this_proto->router_id = $3; }
| DESCRIPTION text { this_proto->dsc = $2; }
| VRF text { this_proto->vrf = if_get_by_name($2); this_proto->vrf_set = 1; }
| VRF DEFAULT { this_proto->vrf = NULL; this_proto->vrf_set = 1; }
;
channel_start: net_type_base
{
$$ = this_channel = channel_config_get(NULL, net_label[$1], $1, this_proto);
};
channel_item_:
TABLE rtable {
if (this_channel->net_type && ($2->addr_type != this_channel->net_type))
cf_error("Incompatible table type");
this_channel->table = $2;
}
| IMPORT imexport { this_channel->in_filter = $2; }
| EXPORT imexport { this_channel->out_filter = $2; }
| RECEIVE LIMIT limit_spec { this_channel->rx_limit = $3; }
| IMPORT LIMIT limit_spec { this_channel->in_limit = $3; }
| EXPORT LIMIT limit_spec { this_channel->out_limit = $3; }
| PREFERENCE expr { this_channel->preference = $2; check_u16($2); }
| IMPORT KEEP FILTERED bool { this_channel->in_keep_filtered = $4; }
| RPKI RELOAD bool { this_channel->rpki_reload = $3; }
;
/* To avoid grammar collision in Pipe protocol */
channel_item:
channel_item_
| DEBUG debug_mask { this_channel->debug = $2; }
;
channel_opts:
/* empty */
| channel_opts channel_item ';'
;
channel_opt_list:
/* empty */
| '{' channel_opts '}'
;
channel_end:
{
if (!this_channel->table)
cf_error("Routing table not specified");
this_channel = NULL;
};
proto_channel: channel_start channel_opt_list channel_end;
rtable: CF_SYM_KNOWN { cf_assert_symbol($1, SYM_TABLE); $$ = $1->table; } ;
imexport:
FILTER filter { $$ = $2; }
| where_filter
| ALL { $$ = FILTER_ACCEPT; }
| NONE { $$ = FILTER_REJECT; }
;
limit_action:
/* default */ { $$ = PLA_DISABLE; }
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| ACTION WARN { $$ = PLA_WARN; }
| ACTION BLOCK { $$ = PLA_BLOCK; }
| ACTION RESTART { $$ = PLA_RESTART; }
| ACTION DISABLE { $$ = PLA_DISABLE; }
;
limit_spec:
expr limit_action { $$ = (struct channel_limit){ .limit = $1, $$.action = $2 }; }
| OFF { $$ = (struct channel_limit){}; }
;
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conf: debug_default ;
debug_default:
DEBUG PROTOCOLS debug_mask { new_config->proto_default_debug = $3; }
| DEBUG CHANNELS debug_mask { new_config->channel_default_debug = $3; }
| DEBUG TABLES debug_mask { new_config->table_default_debug = $3; }
| DEBUG COMMANDS expr { new_config->cli_debug = $3; }
;
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/* MRTDUMP PROTOCOLS is in systep/unix/config.Y */
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conf: timeformat_base ;
timeformat_which:
ROUTE { $$ = &new_config->tf_route; }
| PROTOCOL { $$ = &new_config->tf_proto; }
| BASE { $$ = &new_config->tf_base; }
| LOG { $$ = &new_config->tf_log; }
;
timeformat_spec:
timeformat_which TEXT { *$1 = (struct timeformat){$2, NULL, 0}; }
| timeformat_which TEXT expr TEXT { *$1 = (struct timeformat){$2, $4, (s64) $3 S_}; }
| timeformat_which ISO SHORT { *$1 = TM_ISO_SHORT_S; }
| timeformat_which ISO SHORT MS { *$1 = TM_ISO_SHORT_MS; }
| timeformat_which ISO SHORT US { *$1 = TM_ISO_SHORT_US; }
| timeformat_which ISO LONG { *$1 = TM_ISO_LONG_S; }
| timeformat_which ISO LONG MS { *$1 = TM_ISO_LONG_MS; }
| timeformat_which ISO LONG US { *$1 = TM_ISO_LONG_US; }
;
timeformat_base:
TIMEFORMAT timeformat_spec ';'
;
/* Interface patterns */
iface_patt_node_init:
/* EMPTY */ {
struct iface_patt_node *ipn = cfg_allocz(sizeof(struct iface_patt_node));
add_tail(&this_ipatt->ipn_list, NODE ipn);
this_ipn = ipn;
}
;
iface_patt_node_body:
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TEXT { this_ipn->pattern = $1; /* this_ipn->prefix stays zero */ }
| opttext net_or_ipa { this_ipn->pattern = $1; this_ipn->prefix = $2; }
;
iface_negate:
{ this_ipn->positive = 1; }
| '-' { this_ipn->positive = 0; }
;
iface_patt_node:
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iface_patt_node_init iface_negate iface_patt_node_body
;
iface_patt_list:
iface_patt_node
| iface_patt_list ',' iface_patt_node
;
/* For name/mask-only iface patterns */
iface_patt_list_nopx: iface_patt_list { iface_patt_check(); }
iface_patt_init: {
/* Generic this_ipatt init */
this_ipatt = cfg_allocz(sizeof(struct iface_patt));
init_list(&this_ipatt->ipn_list);
}
;
iface_patt:
iface_patt_init iface_patt_list
;
tos:
CLASS expr { $$ = $2 & 0xfc; if ($2 > 255) cf_error("TX class must be in range 0-255"); }
| DSCP expr { $$ = ($2 & 0x3f) << 2; if ($2 > 63) cf_error("TX DSCP must be in range 0-63"); }
;
/* Direct device route protocol */
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proto: dev_proto '}' ;
dev_proto_start: proto_start DIRECT {
this_proto = proto_config_new(&proto_device, $1);
init_list(&DIRECT_CFG->iface_list);
}
;
dev_proto:
dev_proto_start proto_name '{'
| dev_proto proto_item ';'
| dev_proto proto_channel ';'
| dev_proto dev_iface_patt ';'
| dev_proto CHECK LINK bool ';' { DIRECT_CFG->check_link = $4; }
;
dev_iface_init:
/* EMPTY */ {
this_ipatt = cfg_allocz(sizeof(struct iface_patt));
add_tail(&DIRECT_CFG->iface_list, NODE this_ipatt);
init_list(&this_ipatt->ipn_list);
}
;
dev_iface_patt:
INTERFACE dev_iface_init iface_patt_list
;
Added protocol debugging flags (protocol.h: D_xxx), parsing of them in configuration files and commands for manipulating them. Current debug message policy: o D_STATES, D_ROUTES and D_FILTERS are handled in generic code. o Other debug flags should be handled in the protocols and whenever the flag is set, the corresponding messages should be printed using calls to log(L_TRACE, ...), each message prefixed with the name of the protocol instance. These messages should cover the whole normal operation of the protocol and should be useful for an administrator trying to understand what does the protocol behave on his network or who is attempting to diagnose network problems. If your messages don't fit to the categories I've defined, feel free to add your own ones (by adding them to protocol.h and on two places in nest/config.Y), but please try to keep the categories as general as possible (i.e., not tied to your protocol). o Internal debug messages not interesting even to an experienced user should be printed by calling DBG() which is either void or a call to debug() depending on setting of the LOCAL_DEBUG symbol at the top of your source. o Dump functions (proto->dump etc.) should call debug() to print their messages. o If you are doing any internal consistency checks, use ASSERT or bug(). o Nobody shall ever call printf() or any other stdio functions. Also please try to log any protocol errors you encounter and tag them with the appropriate message category (usually L_REMOTE or L_AUTH). Always carefully check contents of any message field you receive and verify all IP addresses you work with (by calling ipa_classify() or by using the neighbour cache if you want to check direct connectedness as well).
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/* Debug flags */
debug_mask:
ALL { $$ = ~0; }
| OFF { $$ = 0; }
| '{' debug_list '}' { $$ = $2; }
;
debug_list:
debug_flag
| debug_list ',' debug_flag { $$ = $1 | $3; }
;
debug_flag:
STATES { $$ = D_STATES; }
| ROUTES { $$ = D_ROUTES; }
| FILTERS { $$ = D_FILTERS; }
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| INTERFACES { $$ = D_IFACES; }
Added protocol debugging flags (protocol.h: D_xxx), parsing of them in configuration files and commands for manipulating them. Current debug message policy: o D_STATES, D_ROUTES and D_FILTERS are handled in generic code. o Other debug flags should be handled in the protocols and whenever the flag is set, the corresponding messages should be printed using calls to log(L_TRACE, ...), each message prefixed with the name of the protocol instance. These messages should cover the whole normal operation of the protocol and should be useful for an administrator trying to understand what does the protocol behave on his network or who is attempting to diagnose network problems. If your messages don't fit to the categories I've defined, feel free to add your own ones (by adding them to protocol.h and on two places in nest/config.Y), but please try to keep the categories as general as possible (i.e., not tied to your protocol). o Internal debug messages not interesting even to an experienced user should be printed by calling DBG() which is either void or a call to debug() depending on setting of the LOCAL_DEBUG symbol at the top of your source. o Dump functions (proto->dump etc.) should call debug() to print their messages. o If you are doing any internal consistency checks, use ASSERT or bug(). o Nobody shall ever call printf() or any other stdio functions. Also please try to log any protocol errors you encounter and tag them with the appropriate message category (usually L_REMOTE or L_AUTH). Always carefully check contents of any message field you receive and verify all IP addresses you work with (by calling ipa_classify() or by using the neighbour cache if you want to check direct connectedness as well).
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| EVENTS { $$ = D_EVENTS; }
| PACKETS { $$ = D_PACKETS; }
;
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/* MRTDump flags */
mrtdump_mask:
ALL { $$ = ~0; }
| OFF { $$ = 0; }
| '{' mrtdump_list '}' { $$ = $2; }
;
mrtdump_list:
mrtdump_flag
| mrtdump_list ',' mrtdump_flag { $$ = $1 | $3; }
;
mrtdump_flag:
STATES { $$ = MD_STATES; }
| MESSAGES { $$ = MD_MESSAGES; }
;
/* Password lists */
password_list:
password_list_body
;
password_list_body:
PASSWORDS '{' password_items '}'
| password_item
;
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password_items:
/* empty */
| password_item ';' password_items
;
password_item:
password_item_begin '{' password_item_params '}' password_item_end
| password_item_begin password_item_end
;
pass_key: PASSWORD | KEY;
password_item_begin: pass_key bytestring_text
{
init_password_list();
if ($2.type == T_BYTESTRING)
init_password($2.val.bs->data, $2.val.bs->length, password_id++);
else if ($2.type == T_STRING)
init_password($2.val.s, strlen($2.val.s), password_id++);
else bug("Bad bytestring_text");
};
password_item_params:
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/* empty */ { }
| GENERATE FROM time ';' password_item_params { this_p_item->genfrom = $3; }
| GENERATE TO time ';' password_item_params { this_p_item->gento = $3; }
| ACCEPT FROM time ';' password_item_params { this_p_item->accfrom = $3; }
| ACCEPT TO time ';' password_item_params { this_p_item->accto = $3; }
| FROM time ';' password_item_params { this_p_item->genfrom = this_p_item->accfrom = $2; }
| TO time ';' password_item_params { this_p_item->gento = this_p_item->accto = $2; }
| ID expr ';' password_item_params { this_p_item->id = $2; if ($2 > 255) cf_error("Password ID must be in range 0-255"); }
| ALGORITHM password_algorithm ';' password_item_params { this_p_item->alg = $2; }
;
password_algorithm:
KEYED MD5 { $$ = ALG_MD5; }
| KEYED SHA1 { $$ = ALG_SHA1; }
| KEYED SHA256 { $$ = ALG_SHA256; }
| KEYED SHA384 { $$ = ALG_SHA384; }
| KEYED SHA512 { $$ = ALG_SHA512; }
| HMAC MD5 { $$ = ALG_HMAC_MD5; }
| HMAC SHA1 { $$ = ALG_HMAC_SHA1; }
| HMAC SHA256 { $$ = ALG_HMAC_SHA256; }
| HMAC SHA384 { $$ = ALG_HMAC_SHA384; }
| HMAC SHA512 { $$ = ALG_HMAC_SHA512; }
| BLAKE2S128 { $$ = ALG_BLAKE2S_128; }
| BLAKE2S256 { $$ = ALG_BLAKE2S_256; }
| BLAKE2B256 { $$ = ALG_BLAKE2B_256; }
| BLAKE2B512 { $$ = ALG_BLAKE2B_512; }
;
password_item_end:
{
password_validate_length(this_p_item);
};
/* BFD options */
bfd_item:
INTERVAL expr_us { this_bfd_opts->min_rx_int = this_bfd_opts->min_tx_int = $2; }
| MIN RX INTERVAL expr_us { this_bfd_opts->min_rx_int = $4; }
| MIN TX INTERVAL expr_us { this_bfd_opts->min_tx_int = $4; }
| IDLE TX INTERVAL expr_us { this_bfd_opts->idle_tx_int = $4; }
| MULTIPLIER expr { this_bfd_opts->multiplier = $2; }
| PASSIVE bool { this_bfd_opts->passive = $2; this_bfd_opts->passive_set = 1; }
| GRACEFUL { this_bfd_opts->mode = BGP_BFD_GRACEFUL; }
;
bfd_items:
/* empty */
| bfd_items bfd_item ';'
;
bfd_opts:
'{' bfd_items '}'
;
/* Core commands */
CF_CLI_HELP(SHOW, ..., [[Show status information]])
CF_CLI(SHOW STATUS,,, [[Show router status]])
2002-11-13 08:46:12 +00:00
{ cmd_show_status(); } ;
CF_CLI(SHOW MEMORY,,, [[Show memory usage]])
{ cmd_show_memory(); } ;
CF_CLI(SHOW PROTOCOLS, proto_patt2, [<protocol> | \"<pattern>\"], [[Show routing protocols]])
{ proto_apply_cmd($3, proto_cmd_show, 0, 0); } ;
CF_CLI(SHOW PROTOCOLS ALL, proto_patt2, [<protocol> | \"<pattern>\"], [[Show routing protocol details]])
{ proto_apply_cmd($4, proto_cmd_show, 0, 1); } ;
optproto:
CF_SYM_KNOWN { cf_assert_symbol($1, SYM_PROTO); $$ = $1; }
| /* empty */ { $$ = NULL; }
;
CF_CLI(SHOW INTERFACES,,, [[Show network interfaces]])
{ if_show(); } ;
CF_CLI(SHOW INTERFACES SUMMARY,,, [[Show summary of network interfaces]])
{ if_show_summary(); } ;
2012-03-22 10:46:38 +00:00
CF_CLI_HELP(SHOW ROUTE, ..., [[Show routing table]])
CF_CLI(SHOW ROUTE, r_args, [[[<prefix>|for <prefix>|for <ip>|in <prefix>] [table <t>] [(import|export) table <p>.<c>] [filter <f>|where <cond>] [all] [primary] [filtered] [(export|preexport|noexport) <p>] [protocol <p>] [stats|count]]], [[Show routing table]])
{ rt_show($3); } ;
r_args:
/* empty */ {
$$ = cfg_allocz(sizeof(struct rt_show_data));
init_list(&($$->tables));
$$->filter = FILTER_ACCEPT;
$$->running_on_config = config;
}
| r_args net_any {
$$ = $1;
2015-12-24 14:52:03 +00:00
if ($$->addr) cf_error("Only one prefix expected");
$$->addr = $2;
$$->addr_mode = RSD_ADDR_EQUAL;
}
| r_args FOR r_args_for {
$$ = $1;
2015-12-24 14:52:03 +00:00
if ($$->addr) cf_error("Only one prefix expected");
$$->addr = $3;
$$->addr_mode = RSD_ADDR_FOR;
}
| r_args IN net_any {
$$ = $1;
if ($$->addr) cf_error("Only one prefix expected");
if (!net_type_match($3, NB_IP)) cf_error("Only IP networks accepted for 'in' argument");
$$->addr = $3;
$$->addr_mode = RSD_ADDR_IN;
}
| r_args TABLE symbol_known {
cf_assert_symbol($3, SYM_TABLE);
$$ = $1;
rt_show_add_table($$, $3->table->table);
$$->tables_defined_by = RSD_TDB_DIRECT;
}
| r_args TABLE ALL {
struct rtable_config *t;
$$ = $1;
WALK_LIST(t, config->tables)
rt_show_add_table($$, t->table);
$$->tables_defined_by = RSD_TDB_ALL;
}
| r_args IMPORT TABLE channel_arg {
if (!$4->in_table) cf_error("No import table in channel %s.%s", $4->proto->name, $4->name);
rt_show_add_table($$, $4->in_table);
$$->tables_defined_by = RSD_TDB_DIRECT;
}
| r_args EXPORT TABLE channel_arg {
if (!$4->out_table) cf_error("No export table in channel %s.%s", $4->proto->name, $4->name);
rt_show_add_table($$, $4->out_table);
$$->tables_defined_by = RSD_TDB_DIRECT;
}
| r_args FILTER filter {
$$ = $1;
if ($$->filter != FILTER_ACCEPT) cf_error("Filter specified twice");
$$->filter = $3;
}
| r_args where_filter {
$$ = $1;
if ($$->filter != FILTER_ACCEPT) cf_error("Filter specified twice");
$$->filter = $2;
}
| r_args ALL {
$$ = $1;
$$->verbose = 1;
}
| r_args PRIMARY {
$$ = $1;
$$->primary_only = 1;
}
| r_args FILTERED {
$$ = $1;
$$->filtered = 1;
}
| r_args export_mode symbol_known {
cf_assert_symbol($3, SYM_PROTO);
struct proto_config *c = (struct proto_config *) $3->proto;
$$ = $1;
if ($$->export_mode) cf_error("Export specified twice");
if (!c->proto) cf_error("%s is not a protocol", $3->name);
$$->export_mode = $2;
$$->export_protocol = c->proto;
$$->tables_defined_by = RSD_TDB_INDIRECT;
}
| r_args export_mode channel_arg {
$$ = $1;
if ($$->export_mode) cf_error("Export specified twice");
$$->export_mode = $2;
$$->export_channel = $3;
$$->tables_defined_by = RSD_TDB_INDIRECT;
}
| r_args PROTOCOL symbol_known {
cf_assert_symbol($3, SYM_PROTO);
struct proto_config *c = (struct proto_config *) $3->proto;
$$ = $1;
if ($$->show_protocol) cf_error("Protocol specified twice");
if (!c->proto) cf_error("%s is not a protocol", $3->name);
$$->show_protocol = c->proto;
$$->tables_defined_by = RSD_TDB_INDIRECT;
}
2000-05-07 11:28:59 +00:00
| r_args STATS {
$$ = $1;
$$->stats = 1;
}
| r_args COUNT {
$$ = $1;
$$->stats = 2;
}
;
r_args_for:
r_args_for_val {
$$ = cfg_alloc($1.length);
net_copy($$, &$1);
}
| net_vpn4_
| net_vpn6_
| net_ip6_sadr_
| VPN_RD IP4 {
$$ = cfg_alloc(sizeof(net_addr_vpn4));
net_fill_vpn4($$, $2, IP4_MAX_PREFIX_LENGTH, $1);
}
| VPN_RD IP6 {
$$ = cfg_alloc(sizeof(net_addr_vpn6));
net_fill_vpn6($$, $2, IP6_MAX_PREFIX_LENGTH, $1);
}
| IP6 FROM IP6 {
$$ = cfg_alloc(sizeof(net_addr_ip6_sadr));
net_fill_ip6_sadr($$, $1, IP6_MAX_PREFIX_LENGTH, $3, IP6_MAX_PREFIX_LENGTH);
}
| CF_SYM_KNOWN {
if ($1->class == (SYM_CONSTANT | T_IP))
{
$$ = cfg_alloc(ipa_is_ip4(SYM_VAL($1).ip) ? sizeof(net_addr_ip4) : sizeof(net_addr_ip6));
net_fill_ip_host($$, SYM_VAL($1).ip);
}
else if (($1->class == (SYM_CONSTANT | T_NET)) && net_type_match(SYM_VAL($1).net, NB_IP | NB_VPN))
2017-04-28 22:36:35 +00:00
$$ = (net_addr *) SYM_VAL($1).net; /* Avoid const warning */
else
cf_error("IP address or network constant expected");
}
;
r_args_for_val:
net_ip4_
| net_ip6_
| IP4 { net_fill_ip4(&($$), $1, IP4_MAX_PREFIX_LENGTH); }
| IP6 { net_fill_ip6(&($$), $1, IP6_MAX_PREFIX_LENGTH); }
export_mode:
PREEXPORT { $$ = RSEM_PREEXPORT; }
| EXPORT { $$ = RSEM_EXPORT; }
| NOEXPORT { $$ = RSEM_NOEXPORT; }
| EXPORTED { $$ = RSEM_EXPORTED; }
;
/* This is ugly hack */
channel_sym:
IPV4 { $$ = "ipv4"; }
| IPV4_MC { $$ = "ipv4-mc"; }
| IPV4_MPLS { $$ = "ipv4-mpls"; }
| IPV6 { $$ = "ipv6"; }
| IPV6_MC { $$ = "ipv6-mc"; }
| IPV6_MPLS { $$ = "ipv6-mpls"; }
| IPV6_SADR { $$ = "ipv6-sadr"; }
| VPN4 { $$ = "vpn4"; }
| VPN4_MC { $$ = "vpn4-mc"; }
| VPN4_MPLS { $$ = "vpn4-mpls"; }
| VPN6 { $$ = "vpn6"; }
| VPN6_MC { $$ = "vpn6-mc"; }
| VPN6_MPLS { $$ = "vpn6-mpls"; }
| ROA4 { $$ = "roa4"; }
| ROA6 { $$ = "roa6"; }
| FLOW4 { $$ = "flow4"; }
| FLOW6 { $$ = "flow6"; }
| MPLS { $$ = "mpls"; }
| PRI { $$ = "pri"; }
| SEC { $$ = "sec"; }
;
channel_arg:
CF_SYM_KNOWN '.' channel_sym {
cf_assert_symbol($1, SYM_PROTO);
struct proto *p = $1->proto->proto;
if (!p) cf_error("%s is not a protocol", $1->name);
$$ = proto_find_channel_by_name(p, $3);
if (!$$) cf_error("Channel %s.%s not found", $1->name, $3);
}
;
2012-03-22 10:46:38 +00:00
CF_CLI_HELP(SHOW SYMBOLS, ..., [[Show all known symbolic names]])
CF_CLI(SHOW SYMBOLS, sym_args, [table|filter|function|protocol|template|<symbol>], [[Show all known symbolic names]])
{ cmd_show_symbols($3); } ;
sym_args:
/* empty */ {
$$ = cfg_allocz(sizeof(struct sym_show_data));
}
| sym_args TABLE { $$ = $1; $$->type = SYM_TABLE; }
| sym_args FUNCTION { $$ = $1; $$->type = SYM_FUNCTION; }
| sym_args FILTER { $$ = $1; $$->type = SYM_FILTER; }
| sym_args PROTOCOL { $$ = $1; $$->type = SYM_PROTO; }
| sym_args TEMPLATE { $$ = $1; $$->type = SYM_TEMPLATE; }
| sym_args CF_SYM_KNOWN { $$ = $1; $$->sym = $2; }
;
Added protocol debugging flags (protocol.h: D_xxx), parsing of them in configuration files and commands for manipulating them. Current debug message policy: o D_STATES, D_ROUTES and D_FILTERS are handled in generic code. o Other debug flags should be handled in the protocols and whenever the flag is set, the corresponding messages should be printed using calls to log(L_TRACE, ...), each message prefixed with the name of the protocol instance. These messages should cover the whole normal operation of the protocol and should be useful for an administrator trying to understand what does the protocol behave on his network or who is attempting to diagnose network problems. If your messages don't fit to the categories I've defined, feel free to add your own ones (by adding them to protocol.h and on two places in nest/config.Y), but please try to keep the categories as general as possible (i.e., not tied to your protocol). o Internal debug messages not interesting even to an experienced user should be printed by calling DBG() which is either void or a call to debug() depending on setting of the LOCAL_DEBUG symbol at the top of your source. o Dump functions (proto->dump etc.) should call debug() to print their messages. o If you are doing any internal consistency checks, use ASSERT or bug(). o Nobody shall ever call printf() or any other stdio functions. Also please try to log any protocol errors you encounter and tag them with the appropriate message category (usually L_REMOTE or L_AUTH). Always carefully check contents of any message field you receive and verify all IP addresses you work with (by calling ipa_classify() or by using the neighbour cache if you want to check direct connectedness as well).
2000-03-07 20:49:48 +00:00
CF_CLI_HELP(DUMP, ..., [[Dump debugging information]])
CF_CLI(DUMP RESOURCES,,, [[Dump all allocated resource]])
{ rdump(&root_pool); cli_msg(0, ""); } ;
Added protocol debugging flags (protocol.h: D_xxx), parsing of them in configuration files and commands for manipulating them. Current debug message policy: o D_STATES, D_ROUTES and D_FILTERS are handled in generic code. o Other debug flags should be handled in the protocols and whenever the flag is set, the corresponding messages should be printed using calls to log(L_TRACE, ...), each message prefixed with the name of the protocol instance. These messages should cover the whole normal operation of the protocol and should be useful for an administrator trying to understand what does the protocol behave on his network or who is attempting to diagnose network problems. If your messages don't fit to the categories I've defined, feel free to add your own ones (by adding them to protocol.h and on two places in nest/config.Y), but please try to keep the categories as general as possible (i.e., not tied to your protocol). o Internal debug messages not interesting even to an experienced user should be printed by calling DBG() which is either void or a call to debug() depending on setting of the LOCAL_DEBUG symbol at the top of your source. o Dump functions (proto->dump etc.) should call debug() to print their messages. o If you are doing any internal consistency checks, use ASSERT or bug(). o Nobody shall ever call printf() or any other stdio functions. Also please try to log any protocol errors you encounter and tag them with the appropriate message category (usually L_REMOTE or L_AUTH). Always carefully check contents of any message field you receive and verify all IP addresses you work with (by calling ipa_classify() or by using the neighbour cache if you want to check direct connectedness as well).
2000-03-07 20:49:48 +00:00
CF_CLI(DUMP SOCKETS,,, [[Dump open sockets]])
{ sk_dump_all(); cli_msg(0, ""); } ;
CF_CLI(DUMP EVENTS,,, [[Dump event log]])
{ io_log_dump(); cli_msg(0, ""); } ;
Added protocol debugging flags (protocol.h: D_xxx), parsing of them in configuration files and commands for manipulating them. Current debug message policy: o D_STATES, D_ROUTES and D_FILTERS are handled in generic code. o Other debug flags should be handled in the protocols and whenever the flag is set, the corresponding messages should be printed using calls to log(L_TRACE, ...), each message prefixed with the name of the protocol instance. These messages should cover the whole normal operation of the protocol and should be useful for an administrator trying to understand what does the protocol behave on his network or who is attempting to diagnose network problems. If your messages don't fit to the categories I've defined, feel free to add your own ones (by adding them to protocol.h and on two places in nest/config.Y), but please try to keep the categories as general as possible (i.e., not tied to your protocol). o Internal debug messages not interesting even to an experienced user should be printed by calling DBG() which is either void or a call to debug() depending on setting of the LOCAL_DEBUG symbol at the top of your source. o Dump functions (proto->dump etc.) should call debug() to print their messages. o If you are doing any internal consistency checks, use ASSERT or bug(). o Nobody shall ever call printf() or any other stdio functions. Also please try to log any protocol errors you encounter and tag them with the appropriate message category (usually L_REMOTE or L_AUTH). Always carefully check contents of any message field you receive and verify all IP addresses you work with (by calling ipa_classify() or by using the neighbour cache if you want to check direct connectedness as well).
2000-03-07 20:49:48 +00:00
CF_CLI(DUMP INTERFACES,,, [[Dump interface information]])
{ if_dump_all(); cli_msg(0, ""); } ;
Added protocol debugging flags (protocol.h: D_xxx), parsing of them in configuration files and commands for manipulating them. Current debug message policy: o D_STATES, D_ROUTES and D_FILTERS are handled in generic code. o Other debug flags should be handled in the protocols and whenever the flag is set, the corresponding messages should be printed using calls to log(L_TRACE, ...), each message prefixed with the name of the protocol instance. These messages should cover the whole normal operation of the protocol and should be useful for an administrator trying to understand what does the protocol behave on his network or who is attempting to diagnose network problems. If your messages don't fit to the categories I've defined, feel free to add your own ones (by adding them to protocol.h and on two places in nest/config.Y), but please try to keep the categories as general as possible (i.e., not tied to your protocol). o Internal debug messages not interesting even to an experienced user should be printed by calling DBG() which is either void or a call to debug() depending on setting of the LOCAL_DEBUG symbol at the top of your source. o Dump functions (proto->dump etc.) should call debug() to print their messages. o If you are doing any internal consistency checks, use ASSERT or bug(). o Nobody shall ever call printf() or any other stdio functions. Also please try to log any protocol errors you encounter and tag them with the appropriate message category (usually L_REMOTE or L_AUTH). Always carefully check contents of any message field you receive and verify all IP addresses you work with (by calling ipa_classify() or by using the neighbour cache if you want to check direct connectedness as well).
2000-03-07 20:49:48 +00:00
CF_CLI(DUMP NEIGHBORS,,, [[Dump neighbor cache]])
{ neigh_dump_all(); cli_msg(0, ""); } ;
Added protocol debugging flags (protocol.h: D_xxx), parsing of them in configuration files and commands for manipulating them. Current debug message policy: o D_STATES, D_ROUTES and D_FILTERS are handled in generic code. o Other debug flags should be handled in the protocols and whenever the flag is set, the corresponding messages should be printed using calls to log(L_TRACE, ...), each message prefixed with the name of the protocol instance. These messages should cover the whole normal operation of the protocol and should be useful for an administrator trying to understand what does the protocol behave on his network or who is attempting to diagnose network problems. If your messages don't fit to the categories I've defined, feel free to add your own ones (by adding them to protocol.h and on two places in nest/config.Y), but please try to keep the categories as general as possible (i.e., not tied to your protocol). o Internal debug messages not interesting even to an experienced user should be printed by calling DBG() which is either void or a call to debug() depending on setting of the LOCAL_DEBUG symbol at the top of your source. o Dump functions (proto->dump etc.) should call debug() to print their messages. o If you are doing any internal consistency checks, use ASSERT or bug(). o Nobody shall ever call printf() or any other stdio functions. Also please try to log any protocol errors you encounter and tag them with the appropriate message category (usually L_REMOTE or L_AUTH). Always carefully check contents of any message field you receive and verify all IP addresses you work with (by calling ipa_classify() or by using the neighbour cache if you want to check direct connectedness as well).
2000-03-07 20:49:48 +00:00
CF_CLI(DUMP ATTRIBUTES,,, [[Dump attribute cache]])
{ rta_dump_all(); cli_msg(0, ""); } ;
Added protocol debugging flags (protocol.h: D_xxx), parsing of them in configuration files and commands for manipulating them. Current debug message policy: o D_STATES, D_ROUTES and D_FILTERS are handled in generic code. o Other debug flags should be handled in the protocols and whenever the flag is set, the corresponding messages should be printed using calls to log(L_TRACE, ...), each message prefixed with the name of the protocol instance. These messages should cover the whole normal operation of the protocol and should be useful for an administrator trying to understand what does the protocol behave on his network or who is attempting to diagnose network problems. If your messages don't fit to the categories I've defined, feel free to add your own ones (by adding them to protocol.h and on two places in nest/config.Y), but please try to keep the categories as general as possible (i.e., not tied to your protocol). o Internal debug messages not interesting even to an experienced user should be printed by calling DBG() which is either void or a call to debug() depending on setting of the LOCAL_DEBUG symbol at the top of your source. o Dump functions (proto->dump etc.) should call debug() to print their messages. o If you are doing any internal consistency checks, use ASSERT or bug(). o Nobody shall ever call printf() or any other stdio functions. Also please try to log any protocol errors you encounter and tag them with the appropriate message category (usually L_REMOTE or L_AUTH). Always carefully check contents of any message field you receive and verify all IP addresses you work with (by calling ipa_classify() or by using the neighbour cache if you want to check direct connectedness as well).
2000-03-07 20:49:48 +00:00
CF_CLI(DUMP ROUTES,,, [[Dump routing table]])
{ rt_dump_all(); cli_msg(0, ""); } ;
Added protocol debugging flags (protocol.h: D_xxx), parsing of them in configuration files and commands for manipulating them. Current debug message policy: o D_STATES, D_ROUTES and D_FILTERS are handled in generic code. o Other debug flags should be handled in the protocols and whenever the flag is set, the corresponding messages should be printed using calls to log(L_TRACE, ...), each message prefixed with the name of the protocol instance. These messages should cover the whole normal operation of the protocol and should be useful for an administrator trying to understand what does the protocol behave on his network or who is attempting to diagnose network problems. If your messages don't fit to the categories I've defined, feel free to add your own ones (by adding them to protocol.h and on two places in nest/config.Y), but please try to keep the categories as general as possible (i.e., not tied to your protocol). o Internal debug messages not interesting even to an experienced user should be printed by calling DBG() which is either void or a call to debug() depending on setting of the LOCAL_DEBUG symbol at the top of your source. o Dump functions (proto->dump etc.) should call debug() to print their messages. o If you are doing any internal consistency checks, use ASSERT or bug(). o Nobody shall ever call printf() or any other stdio functions. Also please try to log any protocol errors you encounter and tag them with the appropriate message category (usually L_REMOTE or L_AUTH). Always carefully check contents of any message field you receive and verify all IP addresses you work with (by calling ipa_classify() or by using the neighbour cache if you want to check direct connectedness as well).
2000-03-07 20:49:48 +00:00
CF_CLI(DUMP PROTOCOLS,,, [[Dump protocol information]])
{ protos_dump_all(); cli_msg(0, ""); } ;
CF_CLI(DUMP FILTER ALL,,, [[Dump all filters in linearized form]])
{ filters_dump_all(); cli_msg(0, ""); } ;
CF_CLI(EVAL, term, <expr>, [[Evaluate an expression]])
{ cmd_eval(f_linearize($2, 1)); } ;
CF_CLI_HELP(ECHO, ..., [[Control echoing of log messages]])
CF_CLI(ECHO, echo_mask echo_size, (all | off | { debug|trace|info|remote|warning|error|auth [, ...] }) [<buffer-size>], [[Control echoing of log messages]]) {
cli_set_log_echo(this_cli, $2, $3);
cli_msg(0, "");
} ;
echo_mask:
ALL { $$ = ~0; }
| OFF { $$ = 0; }
| '{' log_mask_list '}' { $$ = $2; }
;
echo_size:
/* empty */ { $$ = 4096; }
| NUM {
if ($1 < 256 || $1 > 65536) cf_error("Invalid log buffer size");
$$ = $1;
}
;
CF_CLI(DISABLE, proto_patt opttext, (<protocol> | \"<pattern>\" | all) [message], [[Disable protocol]])
{ proto_apply_cmd($2, proto_cmd_disable, 1, (uintptr_t) $3); } ;
CF_CLI(ENABLE, proto_patt opttext, (<protocol> | \"<pattern>\" | all) [message], [[Enable protocol]])
{ proto_apply_cmd($2, proto_cmd_enable, 1, (uintptr_t) $3); } ;
CF_CLI(RESTART, proto_patt opttext, (<protocol> | \"<pattern>\" | all) [message], [[Restart protocol]])
{ proto_apply_cmd($2, proto_cmd_restart, 1, (uintptr_t) $3); } ;
2009-11-26 19:47:59 +00:00
CF_CLI(RELOAD, proto_patt, <protocol> | \"<pattern>\" | all, [[Reload protocol]])
{ proto_apply_cmd($2, proto_cmd_reload, 1, CMD_RELOAD); } ;
2009-12-14 00:32:37 +00:00
CF_CLI(RELOAD IN, proto_patt, <protocol> | \"<pattern>\" | all, [[Reload protocol (just imported routes)]])
{ proto_apply_cmd($3, proto_cmd_reload, 1, CMD_RELOAD_IN); } ;
2009-12-14 00:32:37 +00:00
CF_CLI(RELOAD OUT, proto_patt, <protocol> | \"<pattern>\" | all, [[Reload protocol (just exported routes)]])
{ proto_apply_cmd($3, proto_cmd_reload, 1, CMD_RELOAD_OUT); } ;
2010-01-03 11:17:52 +00:00
CF_CLI_HELP(DEBUG, ..., [[Control protocol debugging via BIRD logs]])
CF_CLI(DEBUG, debug_args, (<protocol> | <channel> | \"<pattern>\" | all) (all | off | { states|routes|filters|interfaces|events|packets [, ...] }), [[Control protocol debugging via BIRD logs]])
{ /* Done in debug_args */ };
debug_args:
proto_patt debug_mask { proto_apply_cmd($1, proto_cmd_debug, 1, $2); }
| channel_arg debug_mask { channel_cmd_debug($1, $2); }
;
2010-01-03 11:17:52 +00:00
CF_CLI_HELP(MRTDUMP, ..., [[Control protocol debugging via MRTdump files]])
CF_CLI(MRTDUMP, proto_patt mrtdump_mask, (<protocol> | \"<pattern>\" | all) (all | off | { states|messages [, ...] }), [[Control protocol debugging via MRTdump format]])
{ proto_apply_cmd($2, proto_cmd_mrtdump, 1, $3); } ;
CF_CLI(RESTRICT,,,[[Restrict current CLI session to safe commands]])
{ this_cli->restricted = 1; cli_msg(16, "Access restricted"); } ;
Added protocol debugging flags (protocol.h: D_xxx), parsing of them in configuration files and commands for manipulating them. Current debug message policy: o D_STATES, D_ROUTES and D_FILTERS are handled in generic code. o Other debug flags should be handled in the protocols and whenever the flag is set, the corresponding messages should be printed using calls to log(L_TRACE, ...), each message prefixed with the name of the protocol instance. These messages should cover the whole normal operation of the protocol and should be useful for an administrator trying to understand what does the protocol behave on his network or who is attempting to diagnose network problems. If your messages don't fit to the categories I've defined, feel free to add your own ones (by adding them to protocol.h and on two places in nest/config.Y), but please try to keep the categories as general as possible (i.e., not tied to your protocol). o Internal debug messages not interesting even to an experienced user should be printed by calling DBG() which is either void or a call to debug() depending on setting of the LOCAL_DEBUG symbol at the top of your source. o Dump functions (proto->dump etc.) should call debug() to print their messages. o If you are doing any internal consistency checks, use ASSERT or bug(). o Nobody shall ever call printf() or any other stdio functions. Also please try to log any protocol errors you encounter and tag them with the appropriate message category (usually L_REMOTE or L_AUTH). Always carefully check contents of any message field you receive and verify all IP addresses you work with (by calling ipa_classify() or by using the neighbour cache if you want to check direct connectedness as well).
2000-03-07 20:49:48 +00:00
proto_patt:
CF_SYM_KNOWN { cf_assert_symbol($1, SYM_PROTO); $$.ptr = $1; $$.patt = 0; }
| ALL { $$.ptr = NULL; $$.patt = 1; }
| TEXT { $$.ptr = $1; $$.patt = 1; }
;
proto_patt2:
CF_SYM_KNOWN { cf_assert_symbol($1, SYM_PROTO); $$.ptr = $1; $$.patt = 0; }
| { $$.ptr = NULL; $$.patt = 1; }
| TEXT { $$.ptr = $1; $$.patt = 1; }
;
2018-06-26 12:29:03 +00:00
dynamic_attr: IGP_METRIC { $$ = f_new_dynamic_attr(EAF_TYPE_INT, T_INT, EA_GEN_IGP_METRIC); } ;
2010-08-02 11:11:53 +00:00
dynamic_attr: MPLS_LABEL { $$ = f_new_dynamic_attr(EAF_TYPE_INT, T_INT, EA_MPLS_LABEL); } ;
dynamic_attr: MPLS_POLICY { $$ = f_new_dynamic_attr(EAF_TYPE_INT, T_ENUM_MPLS_POLICY, EA_MPLS_POLICY); } ;
dynamic_attr: MPLS_CLASS { $$ = f_new_dynamic_attr(EAF_TYPE_INT, T_INT, EA_MPLS_CLASS); } ;
CF_CODE
CF_END