freebsd-nq/usr.sbin/pim6sd/cfparse.y
Kris Kennaway 5bca844f39 Sync with latest KAME code.
Obtained from:	KAME
2000-07-06 01:48:08 +00:00

1024 lines
24 KiB
Plaintext

/*
* Copyright (C) 1999 WIDE Project.
* All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions
* are met:
* 1. Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* 2. Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
* 3. Neither the name of the project nor the names of its contributors
* may be used to endorse or promote products derived from this software
* without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE PROJECT AND CONTRIBUTORS ``AS IS'' AND
* ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
* IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
* ARE DISCLAIMED. IN NO EVENT SHALL THE PROJECT OR CONTRIBUTORS BE LIABLE
* FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
* DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
* OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
* HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
* LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
* OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
* SUCH DAMAGE.
*
* $FreeBSD$
*/
%{
#include <sys/types.h>
#include <netinet/in.h>
#include <arpa/inet.h>
#include <string.h>
#include <syslog.h>
#include "defs.h"
#include "rp.h"
#include "vif.h"
#include "var.h"
#include "vmbuf.h"
#include "cfparse.h"
#include "debug.h"
#include "pimd.h"
#include "timer.h"
#include "inet6.h"
#define set_param(var,val,p) \
do {\
if ((var) != -1) {\
yywarn("%s doubly defined(ignore %d)", (p), (val));\
}\
else {\
(var) = val;\
}\
} while(0)
struct in6_prefix {
struct in6_addr paddr;
int plen;
};
struct attr_list {
struct attr_list *next;
int type;
union {
unsigned int flags;
double number;
struct in6_prefix prefix;
}attru;
};
enum {IFA_FLAG, IFA_PREFERENCE, IFA_METRIC, RPA_PRIORITY, RPA_TIME,
BSRA_PRIORITY, BSRA_TIME, BSRA_MASKLEN, IN6_PREFIX, THRESA_RATE,
THRESA_INTERVAL};
static int strict; /* flag if the grammer check is strict */
static struct attr_list *rp_attr, *bsr_attr, *grp_prefix, *regthres_attr,
*datathres_attr;
static char *cand_rp_ifname, *cand_bsr_ifname;
static int srcmetric, srcpref, helloperiod, jpperiod, granularity,
datatimo, regsuptimo, probetime, asserttimo;
static double helloperiod_coef, jpperiod_coef;
static int debugonly;
extern int yylex __P((void));
%}
%union {
unsigned long num;
double fl;
vchar_t val;
struct attr_list *attr;
}
%token EOS
%token LOGGING LOGLEV NOLOGLEV
%token YES NO
%token REVERSELOOKUP
%token PHYINT IFNAME DISABLE PREFERENCE METRIC NOLISTENER
%token GRPPFX
%token CANDRP CANDBSR TIME PRIORITY MASKLEN
%token NUMBER STRING SLASH
%token REGTHRES DATATHRES RATE INTERVAL
%token SRCMETRIC SRCPREF HELLOPERIOD GRANULARITY JPPERIOD
%token DATATIME REGSUPTIME PROBETIME ASSERTTIME
%type <num> LOGLEV NOLOGLEV
%type <fl> NUMBER
%type <val> STRING IFNAME
%type <attr> if_attributes rp_substatement rp_attributes
%type <attr> bsr_substatement bsr_attributes thres_attributes
%%
statements:
/* empty */
| statements statement
;
statement:
logging_statement
| reverselookup_statement
| phyint_statement
| candrp_statement
| candbsr_statement
| grppfx_statement
| regthres_statement
| datathres_statement
| param_statement
;
/* logging */
logging_statement:
LOGGING log_specs EOS
;
log_specs:
/* empty */
| log_specs LOGLEV {debug |= $2;}
| log_specs NOLOGLEV {debug &= ~($2);}
;
/* reverselookup */
reverselookup_statement:
REVERSELOOKUP YES EOS { numerichost = FALSE; }
| REVERSELOOKUP NO EOS { numerichost = TRUE; }
;
/* phyint */
phyint_statement:
PHYINT IFNAME if_attributes EOS {
struct uvif *v;
v = find_vif($2.v);
free($2.v); /* XXX */
if (v == NULL) {
yywarn("unknown interface: %s", $2.v);
free_attr_list($3);
if (strict)
return(-1);
}
else {
struct attr_list *p;
for (p = (struct attr_list *)v->config_attr;
p && p->next; p = p->next)
;
if (p)
p->next = (void *)$3;
else
v->config_attr = (void *)$3;
}
}
;
if_attributes:
{ $$ = NULL; }
| if_attributes DISABLE
{
if (($$ = add_attribute_flag($1, IFA_FLAG,
VIFF_DISABLED)) == NULL)
return(-1);
}
| if_attributes NOLISTENER
{
if (($$ = add_attribute_flag($1, IFA_FLAG,
VIFF_NOLISTENER)) == NULL)
return(-1);
}
| if_attributes PREFERENCE NUMBER
{
if (($$ = add_attribute_num($1, IFA_PREFERENCE, $3))
== NULL)
return(-1);
}
| if_attributes METRIC NUMBER
{
if (($$ = add_attribute_num($1, IFA_METRIC, $3))
== NULL)
return(-1);
}
;
/* cand_rp */
candrp_statement:
CANDRP rp_substatement EOS {
if (cand_rp_flag == TRUE) {
yywarn("cand_rp doubly defined");
free_attr_list($2);
if (strict)
return(-1);
}
else {
cand_rp_flag = TRUE;
rp_attr = $2;
}
}
;
/* XXX: intermediate rule to avoid shift-reduce conflict */
rp_substatement:
IFNAME rp_attributes
{
if (cand_rp_ifname) {
yywarn("ifname for cand_rp doubly defined");
if (strict)
return(-1);
}
else
cand_rp_ifname = $1.v;
$$ = $2;
}
| rp_attributes
;
rp_attributes:
{ $$ = NULL; }
| rp_attributes PRIORITY NUMBER
{
if (($$ = add_attribute_num($1, RPA_PRIORITY, $3))
== NULL)
return(-1);
}
| rp_attributes TIME NUMBER
{
if (($$ = add_attribute_num($1, RPA_TIME, $3))
== NULL)
return(-1);
}
;
/* cand_bootstrap_router */
candbsr_statement:
CANDBSR bsr_substatement EOS {
if (cand_bsr_flag == TRUE) {
yywarn("cand_bsr doubly defined");
free_attr_list($2);
if (strict)
return(-1);
}
else {
cand_bsr_flag = TRUE;
bsr_attr = $2;
}
}
;
/* XXX: intermediate rule to avoid shift-reduce conflict */
bsr_substatement:
IFNAME bsr_attributes
{
if (cand_bsr_ifname) {
yywarn("ifname for cand_bsr doubly defined");
if (strict)
return(-1);
}
else
cand_bsr_ifname = $1.v;
$$ = $2;
}
| bsr_attributes
;
bsr_attributes:
{ $$ = NULL; }
| bsr_attributes PRIORITY NUMBER
{
if (($$ = add_attribute_num($1, BSRA_PRIORITY, $3))
== NULL)
return(-1);
}
| bsr_attributes TIME NUMBER
{
if (($$ = add_attribute_num($1, BSRA_TIME, $3))
== NULL)
return(-1);
}
| bsr_attributes MASKLEN NUMBER
{
int masklen = $3;
if (masklen < 0 || masklen > 128)
yywarn("invalid mask length: %d (ignored)",
masklen);
else if (($$ = add_attribute_num($1, BSRA_MASKLEN,
masklen))
== NULL)
return(-1);
}
;
/* group_prefix <group-addr>/<prefix_len> */
grppfx_statement:
GRPPFX STRING SLASH NUMBER EOS {
struct in6_prefix prefix;
int prefixok = 1;
if (inet_pton(AF_INET6, $2.v, &prefix.paddr) != 1) {
yywarn("invalid IPv6 address: %s (ignored)", $2);
prefixok = 0;
}
free($2.v); /* XXX: which was allocated dynamically */
prefix.plen = $4;
if (prefix.plen < 0 || prefix.plen > 128) {
yywarn("invalid prefix length: %d (ignored)",
prefix.plen);
prefixok = 0;
}
if (IN6_IS_ADDR_MC_NODELOCAL(&prefix.paddr) ||
IN6_IS_ADDR_MC_LINKLOCAL(&prefix.paddr)) {
yywarn("group prefix (%s/%d) has a narrow scope "
"(ignored)",
inet6_fmt(&prefix.paddr), prefix.plen);
prefixok = 0;
}
if (prefixok) {
struct attr_list *new;
if ((new = malloc(sizeof(*new))) == NULL) {
yyerror("malloc failed");
return(NULL);
}
memset(new, 0, sizeof(*new));
new->type = IN6_PREFIX;
new->attru.prefix = prefix;
new->next = grp_prefix;
grp_prefix = new;
}
}
;
/*
* switch_register_threshold [rate <number> interval <number>]
* Operation: reads and assigns the switch to the spt threshold
* due to registers for the router, if used as RP.
* Maybe extended to support different thresholds for different
* groups(prefixes).
*/
regthres_statement:
REGTHRES thres_attributes EOS {
if (regthres_attr) {
yywarn("switch_register_threshold doubly defined");
free_attr_list($2);
if (strict)
return(-1);
}
else
regthres_attr = $2;
}
;
thres_attributes:
{ $$ = NULL; }
| thres_attributes RATE NUMBER
{
if (($$ = add_attribute_num($1, THRESA_RATE, $3))
== NULL)
return(-1);
}
| thres_attributes INTERVAL NUMBER
{
if (($$ = add_attribute_num($1, THRESA_INTERVAL, $3))
== NULL)
return(-1);
}
/*
* switch_data_threshold [rate <number> interval <number>]
* Operation: reads and assigns the switch to the spt threshold due to
* data packets, if used as DR.
*/
datathres_statement:
DATATHRES thres_attributes EOS {
if (datathres_attr) {
yywarn("switch_data_threshold doubly defined");
free_attr_list($2);
if (strict)
return(-1);
}
else
datathres_attr = $2;
}
;
param_statement:
SRCMETRIC NUMBER EOS
{
set_param(srcmetric, $2, "default_source_metric");
}
| SRCPREF NUMBER EOS
{
set_param(srcpref, $2, "default_source_preference");
}
| HELLOPERIOD NUMBER EOS
{
set_param(helloperiod, $2, "hello_period");
}
| HELLOPERIOD NUMBER NUMBER EOS
{
set_param(helloperiod, $2, "hello_period");
set_param(helloperiod_coef, $3, "hello_period(coef)");
}
| JPPERIOD NUMBER EOS
{
set_param(jpperiod, $2, "join_prune_period");
}
| JPPERIOD NUMBER NUMBER EOS
{
set_param(jpperiod, $2, "join_prune_period");
set_param(jpperiod_coef, $3, "join_prune_period(coef)");
}
| GRANULARITY NUMBER EOS
{
set_param(granularity, $2, "granularity");
}
| DATATIME NUMBER EOS
{
set_param(datatimo, $2, "data_timeout");
}
| REGSUPTIME NUMBER EOS
{
set_param(regsuptimo, $2, "register_suppression_timeout");
}
| PROBETIME NUMBER EOS
{
set_param(probetime, $2, "probe_time");
}
| ASSERTTIME NUMBER EOS
{
set_param(asserttimo, $2, "assert_timeout");
}
;
%%
static struct attr_list *add_attribute_flag __P((struct attr_list *, int,
unsigned int));
static struct attr_list *add_attribute_num __P((struct attr_list *, int,
double));
static void free_attr_list __P((struct attr_list *));
static int param_config __P((void));
static int phyint_config __P((void));
static int rp_config __P((void));
static int bsr_config __P((void));
static int grp_prefix_config __P((void));
static int regthres_config __P((void));
static int datathres_config __P((void));
static struct attr_list *
add_attribute_flag(list, type, flag)
struct attr_list *list;
int type;
unsigned int flag;
{
struct attr_list *p;
if ((p = malloc(sizeof(*p))) == NULL) {
yyerror("malloc failed");
return(NULL);
}
memset((void *)p, 0, sizeof(*p));
p->type = type;
p->attru.flags = flag;
p->next = list;
return(p);
}
/* XXX: too many dup code... */
static struct attr_list *
add_attribute_num(list, type, num)
struct attr_list *list;
int type;
double num;
{
struct attr_list *p;
if ((p = malloc(sizeof(*p))) == NULL) {
yyerror("malloc failed");
return(NULL);
}
memset((void *)p, 0, sizeof(*p));
p->type = type;
p->attru.number = num;
p->next = list;
return(p);
}
static void
free_attr_list(list)
struct attr_list *list;
{
struct attr_list *p, *next;
for(p = list; p; p = next) {
next = p->next;
free(p);
}
}
static int
param_config()
{
struct uvif *v;
vifi_t vifi;
/* at first, set the default values to all the undefined variables */
if (srcmetric == -1) srcmetric = DEFAULT_LOCAL_METRIC;
if (srcpref == -1) srcpref = DEFAULT_LOCAL_PREF;
if (helloperiod == -1) helloperiod = PIM_TIMER_HELLO_PERIOD;
if (helloperiod_coef == -1) helloperiod_coef = 3.5;
if (jpperiod == -1) jpperiod = PIM_JOIN_PRUNE_PERIOD;
if (jpperiod_coef == -1) jpperiod_coef = 3.5;
if (granularity == -1) granularity = DEFAULT_TIMER_INTERVAL;
if (datatimo == -1) datatimo = PIM_DATA_TIMEOUT;
if (regsuptimo == -1) regsuptimo = PIM_REGISTER_SUPPRESSION_TIMEOUT;
if (probetime == -1) probetime = PIM_REGISTER_PROBE_TIME;
if (asserttimo == -1) asserttimo = PIM_ASSERT_TIMEOUT;
/* set protocol parameters using the configuration variables */
for (vifi = 0, v = uvifs; vifi < MAXVIFS; ++vifi, ++v) {
v->uv_local_metric = srcmetric;
v->uv_local_pref = srcpref;
}
pim_hello_period = helloperiod;
pim_hello_holdtime = helloperiod * helloperiod_coef;
pim_join_prune_period = jpperiod;
pim_join_prune_holdtime = jpperiod * jpperiod_coef;
timer_interval = granularity;
pim_data_timeout = datatimo;
pim_register_suppression_timeout = regsuptimo;
pim_register_probe_time = probetime;
pim_assert_timeout = asserttimo;
IF_DEBUG(DEBUG_PIM_HELLO) {
log(LOG_DEBUG, 0, "pim_hello_period set to: %u",
pim_hello_period);
log(LOG_DEBUG, 0, "pim_hello_holdtime set to: %u",
pim_hello_holdtime);
}
IF_DEBUG(DEBUG_PIM_JOIN_PRUNE) {
log(LOG_DEBUG,0 , "pim_join_prune_period set to: %u",
pim_join_prune_period);
log(LOG_DEBUG, 0, "pim_join_prune_holdtime set to: %u",
pim_join_prune_holdtime);
}
IF_DEBUG(DEBUG_TIMER) {
log(LOG_DEBUG,0 , "timer interval set to: %u", timer_interval);
}
IF_DEBUG(DEBUG_PIM_TIMER) {
log(LOG_DEBUG,0 , "PIM data timeout set to: %u",
pim_data_timeout);
}
IF_DEBUG(DEBUG_PIM_REGISTER) {
log(LOG_DEBUG, 0,
"PIM register suppression timeout set to: %u",
pim_register_suppression_timeout);
log(LOG_DEBUG, 0, "PIM register probe time set to: %u",
pim_register_probe_time);
}
IF_DEBUG(DEBUG_PIM_ASSERT) {
log(LOG_DEBUG, 0,
"PIM assert timeout set to: %u",
pim_assert_timeout);
}
return(0);
}
static int
phyint_config()
{
struct uvif *v;
vifi_t vifi;
struct attr_list *al;
for (vifi = 0, v = uvifs; vifi < numvifs ; ++vifi , ++v) {
for (al = (struct attr_list *)v->config_attr; al; al = al->next) {
switch(al->type) {
case IFA_FLAG:
v->uv_flags |= al->attru.flags;
break;
case IFA_PREFERENCE:
if (al->attru.number < 1 ||
al->attru.number > 255)
yywarn("invalid phyint preference(%d)",
(int)al->attru.number);
else {
v->uv_local_pref = al->attru.number;
IF_DEBUG(DEBUG_ASSERT)
log(LOG_DEBUG, 0,
"default localpref for %s "
"is %d",
v->uv_name,
v->uv_local_pref);
}
break;
case IFA_METRIC:
if (al->attru.number < 1 ||
al->attru.number > 1024)
yywarn("invalid metric(%d)",
al->attru.number);
else {
v->uv_metric = al->attru.number;
IF_DEBUG(DEBUG_ASSERT)
log(LOG_DEBUG, 0,
"default local metric for %s "
"is %d",
v->uv_name,
v->uv_metric);
}
break;
}
}
}
return(0);
}
static int
rp_config()
{
struct sockaddr_in6 *sa6_rp = NULL;
struct attr_list *al;
u_int8 *data_ptr;
/* initialization by default values */
my_cand_rp_adv_period = PIM_DEFAULT_CAND_RP_ADV_PERIOD;
my_cand_rp_priority = PIM_DEFAULT_CAND_RP_PRIORITY;
if (cand_rp_ifname) {
sa6_rp = local_iface(cand_rp_ifname);
if (!sa6_rp)
log(LOG_WARNING, 0,
"cand_rp '%s' is not configured. "
"take the max local address the router..",
cand_rp_ifname);
}
for (al = rp_attr; al; al = al->next) {
switch(al->type) {
case RPA_PRIORITY:
if (al->attru.number < 0)
my_cand_rp_priority =
PIM_DEFAULT_CAND_RP_PRIORITY;
else
my_cand_rp_priority = al->attru.number;
break;
case RPA_TIME:
if (al->attru.number < 10)
my_cand_rp_adv_period = 10;
else if (al->attru.number > PIM_DEFAULT_CAND_RP_ADV_PERIOD)
my_cand_rp_adv_period =
PIM_DEFAULT_CAND_RP_ADV_PERIOD;
else
my_cand_rp_adv_period = al->attru.number;
break;
default:
yywarn("unknown attribute(%d) for RP", al->type);
break;
}
}
if (!sa6_rp)
sa6_rp = max_global_address(); /* this MUST suceed */
my_cand_rp_address = *sa6_rp;
/*
* initialize related parameters
*/
/*
* Note that sizeof(pim6_enocd_uni_addr_t) might be larger than
* the length of the Encoded-Unicast-address field(18 byte) due to
* some padding put in the compiler. However, it doesn't matter
* since we use the space just as a buffer(i.e not as the message).
*/
cand_rp_adv_message.buffer = (u_int8 *)malloc(4 +
sizeof(pim6_encod_uni_addr_t) +
255*sizeof(pim6_encod_grp_addr_t));
if(cand_rp_adv_message.buffer == NULL)
log(LOG_ERR, 0, "Candrpadv Buffer allocation");
cand_rp_adv_message.prefix_cnt_ptr = cand_rp_adv_message.buffer;
/*
* By default, if no group_prefix configured, then prefix_cnt == 0
* implies group_prefix = ff00::/8 and masklen = 8.
*/
*cand_rp_adv_message.prefix_cnt_ptr = 0;
cand_rp_adv_message.insert_data_ptr = cand_rp_adv_message.buffer;
/* TODO: XXX: HARDCODING!!! */
cand_rp_adv_message.insert_data_ptr += (4 + 18);
cand_rp_adv_message.message_size =
cand_rp_adv_message.insert_data_ptr - cand_rp_adv_message.buffer;
my_cand_rp_holdtime = 2.5 * my_cand_rp_adv_period;
/* TODO: HARDCODING! */
data_ptr = cand_rp_adv_message.buffer + 1; /* WARNING */
PUT_BYTE(my_cand_rp_priority,data_ptr);
PUT_HOSTSHORT(my_cand_rp_holdtime, data_ptr);
PUT_EUADDR6(my_cand_rp_address.sin6_addr,data_ptr);
IF_DEBUG(DEBUG_PIM_CAND_RP) {
log(LOG_DEBUG, 0,
"Local Cand-RP address is : %s",
inet6_fmt(&my_cand_rp_address.sin6_addr));
log(LOG_DEBUG, 0,
"Local Cand-RP priority is : %u",my_cand_rp_priority);
log(LOG_DEBUG, 0,
"Local Cand-RP advertisement period is : %u sec.",
my_cand_rp_adv_period);
}
return(0);
}
static int
bsr_config()
{
struct sockaddr_in6 *sa6_bsr = NULL;
struct attr_list *al;
int my_bsr_hash_masklen;
/* initialization by default values */
my_bsr_period = PIM_DEFAULT_BOOTSTRAP_PERIOD;
my_bsr_priority = PIM_DEFAULT_BSR_PRIORITY;
my_bsr_hash_masklen = RP_DEFAULT_IPV6_HASHMASKLEN;
if (cand_bsr_ifname) {
sa6_bsr = local_iface(cand_bsr_ifname);
if (!sa6_bsr)
log(LOG_WARNING, 0,
"bsr '%s' is not configured. "
"take the max local address the router..",
cand_bsr_ifname);
}
for (al = bsr_attr; al; al = al->next) {
switch(al->type) {
case BSRA_PRIORITY:
if (al->attru.number >= 0)
my_bsr_priority = al->attru.number;
break;
case BSRA_MASKLEN:
/* validation has been done. */
my_bsr_hash_masklen = al->attru.number;
break;
case BSRA_TIME:
if (al->attru.number < 10)
my_bsr_period = 10;
else if (al->attru.number > PIM_DEFAULT_BOOTSTRAP_PERIOD)
my_bsr_period =
PIM_DEFAULT_BOOTSTRAP_PERIOD;
else
my_bsr_period = al->attru.number;
break;
default:
yywarn("unknown attribute(%d) for BSR", al->type);
break;
}
}
if (!sa6_bsr)
sa6_bsr = max_global_address(); /* this MUST suceed */
my_bsr_address = *sa6_bsr;
MASKLEN_TO_MASK6(my_bsr_hash_masklen, my_bsr_hash_mask);
IF_DEBUG(DEBUG_PIM_BOOTSTRAP) {
log(LOG_DEBUG, 0, "Local BSR address: %s",
inet6_fmt(&my_bsr_address.sin6_addr));
log(LOG_DEBUG, 0, "Local BSR priority : %u", my_bsr_priority);
log(LOG_DEBUG, 0, "Local BSR period is : %u sec.",
my_bsr_period);
log(LOG_DEBUG, 0, "Local BSR hash mask length: %d",
my_bsr_hash_masklen);
}
return(0);
}
static int
grp_prefix_config()
{
struct attr_list *pl;
if (cand_rp_flag != TRUE) {
log(LOG_WARNING, 0,
"group_prefix was specified without cand_rp(ignored)");
return(0);
}
for (pl = grp_prefix; pl; pl = pl->next) {
if (!IN6_IS_ADDR_MULTICAST(&pl->attru.prefix.paddr)) {
log(LOG_WARNING, 0,
"Config error: %s is not a mulicast address(ignored)",
inet6_fmt(&pl->attru.prefix.paddr));
continue;
}
if (!(~(*cand_rp_adv_message.prefix_cnt_ptr))) {
log(LOG_WARNING, 0,
"Too many group_prefix configured. Truncating...");
break;
}
/* validation for plen has almost done */
if (pl->attru.prefix.plen < PIM_GROUP_PREFIX_DEFAULT_MASKLEN)
pl->attru.prefix.plen = PIM_GROUP_PREFIX_DEFAULT_MASKLEN;
PUT_EGADDR6(pl->attru.prefix.paddr,
(u_int8)pl->attru.prefix.plen, 0,
cand_rp_adv_message.insert_data_ptr);
(*cand_rp_adv_message.prefix_cnt_ptr)++;
}
/* finally, adjust the data size */
cand_rp_adv_message.message_size =
cand_rp_adv_message.insert_data_ptr - cand_rp_adv_message.buffer;
return(0);
}
static int
regthres_config()
{
struct attr_list *al;
int rate = -1;
int interval = -1;
if (cand_rp_flag != TRUE) {
log(LOG_WARNING, 0,
"register_threshold was specified without cand_rp");
}
for (al = regthres_attr; al; al = al->next) {
switch(al->type) {
case THRESA_RATE:
if (al->attru.number < 0)
yywarn("invalid regthres rate: %d(ignored)",
al->attru.number);
else if (rate != -1)
yywarn("regthres rate is doubly defined(ignored)");
else
rate = al->attru.number;
break;
case THRESA_INTERVAL:
if (al->attru.number < 0)
yywarn("invalid regthres interval: %d(ignored)",
al->attru.number);
else if (interval != -1)
yywarn("regthres interval is doubly defined(ignored)");
else
interval = al->attru.number;
break;
default:
yywarn("unknown attribute(%d) for regthres", al->type);
break;
}
}
/* set default values if not specified */
if (rate == -1)
rate = PIM_DEFAULT_REG_RATE;
if (interval == -1)
interval = PIM_DEFAULT_REG_RATE_INTERVAL;
pim_reg_rate_bytes = (rate * interval ) /10;
pim_reg_rate_check_interval = interval;
return(0);
}
static int
datathres_config()
{
struct attr_list *al;
int rate = -1;
int interval = -1;
for (al = datathres_attr; al; al = al->next) {
switch(al->type) {
case THRESA_RATE:
if (al->attru.number < 0)
yywarn("invalid datathres rate: %d(ignored)",
al->attru.number);
else if (rate != -1)
yywarn("datathres rate is doubly defined(ignored)");
else
rate = al->attru.number;
break;
case THRESA_INTERVAL:
if (al->attru.number < 0)
yywarn("invalid datathres interval: %d(ignored)",
al->attru.number);
else if (interval != -1)
yywarn("datathres interval is doubly defined(ignored)");
else
interval = al->attru.number;
break;
default:
yywarn("unknown attribute(%d) for datathres", al->type);
break;
}
}
/* set default values if not specified */
if (rate == -1)
rate = PIM_DEFAULT_DATA_RATE;
if (interval == -1)
interval = PIM_DEFAULT_DATA_RATE_INTERVAL;
pim_data_rate_bytes = (rate * interval ) /10;
pim_data_rate_check_interval = interval;
return(0);
}
int
cf_post_config()
{
struct uvif *v;
vifi_t vifi;
if (debugonly)
goto cleanup;
param_config(); /* must be called before phyint_conifg() */
phyint_config();
if (cand_bsr_flag == TRUE)
bsr_config();
if (cand_rp_flag == TRUE)
rp_config();
if (grp_prefix) /* this must be called after rp_config() */
grp_prefix_config();
if (cand_rp_flag == TRUE)
regthres_config();
datathres_config();
IF_DEBUG(DEBUG_SWITCH) {
log(LOG_DEBUG, 0, "reg_rate_limit set to %u (bits/s)",
pim_reg_rate_bytes);
log(LOG_DEBUG, 0, "reg_rate_interval set to %u s.",
pim_reg_rate_check_interval);
log(LOG_DEBUG, 0, "data_rate_limit set to %u (bits/s)",
pim_data_rate_bytes);
log(LOG_DEBUG, 0, "data_rate_interval set to %u s.",
pim_data_rate_check_interval);
}
cleanup:
/* cleanup temporary variables */
if (cand_rp_ifname) free(cand_rp_ifname);
if (cand_bsr_ifname) free(cand_bsr_ifname);
if (rp_attr) free_attr_list(rp_attr);
if (bsr_attr) free_attr_list(bsr_attr);
if (grp_prefix) free_attr_list(grp_prefix);
if (regthres_attr) free_attr_list(regthres_attr);
if (datathres_attr) free_attr_list(datathres_attr);
for (vifi = 0, v = uvifs; vifi < numvifs ; ++vifi , ++v)
free_attr_list((struct attr_list *)v->config_attr);
return(0);
}
/* initialize all the temporary variables */
void
cf_init(s, d)
{
struct uvif *v;
vifi_t vifi;
strict = s;
debugonly = d;
debug = 0;
rp_attr = bsr_attr = grp_prefix = regthres_attr = datathres_attr = NULL;
cand_rp_ifname = cand_bsr_ifname = NULL;
srcmetric = srcpref = helloperiod = jpperiod = jpperiod_coef
= granularity = datatimo = regsuptimo = probetime
= asserttimo = -1;
helloperiod_coef = jpperiod_coef = -1;
for (vifi = 0, v = uvifs; vifi < numvifs ; ++vifi , ++v)
v->config_attr = NULL;
}