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owipcalc: add new operations "next", "prev", "6to4" and "pop", implement a stack for intermediate results

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SVN-Revision: 32785
v19.07.3_mercusys_ac12_duma
Jo-Philipp Wich 12 years ago
parent 015d66cffb
commit 585ebed25f
2 changed files with 266 additions and 101 deletions
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2
package/owipcalc/Makefile
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@ -7,7 +7,7 @@
include $(TOPDIR)/rules.mk include $(TOPDIR)/rules.mk
PKG_NAME:=owipcalc PKG_NAME:=owipcalc
PKG_RELEASE:=2 PKG_RELEASE:=3
include $(INCLUDE_DIR)/package.mk include $(INCLUDE_DIR)/package.mk

365
package/owipcalc/src/owipcalc.c
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@ -36,8 +36,9 @@ struct cidr {
} addr; } addr;
union { union {
char v4[sizeof("255.255.255.255/255.255.255.255 ")]; char v4[sizeof("255.255.255.255/255.255.255.255 ")];
char v6[sizeof("FFFF:FFFF:FFFF:FFFF:FFFF:FFFF:FFFF:FFFF/128 ")]; char v6[sizeof("FFFF:FFFF:FFFF:FFFF:FFFF:FFFF:255.255.255.255/128 ")];
} buf; } buf;
struct cidr *next;
}; };
struct op { struct op {
@ -57,6 +58,54 @@ struct op {
static bool quiet = false; static bool quiet = false;
static bool printed = false; static bool printed = false;
static struct cidr *stack = NULL;
#define qprintf(...) \
do { \
if (!quiet) printf(__VA_ARGS__); \
printed = true; \
} while(0)
static void cidr_push(struct cidr *a)
{
if (a)
{
a->next = stack;
stack = a;
}
}
static bool cidr_pop(struct cidr *a)
{
struct cidr *old = stack;
if (old)
{
stack = stack->next;
free(old);
return true;
}
return false;
}
static struct cidr * cidr_clone(struct cidr *a)
{
struct cidr *b = malloc(sizeof(*b));
if (!b)
{
fprintf(stderr, "out of memory\n");
exit(255);
}
memcpy(b, a, sizeof(*b));
cidr_push(b);
return b;
}
static struct cidr * cidr_parse4(const char *s) static struct cidr * cidr_parse4(const char *s)
{ {
@ -115,7 +164,9 @@ static bool cidr_add4(struct cidr *a, struct cidr *b)
uint32_t x = ntohl(a->addr.v4.s_addr); uint32_t x = ntohl(a->addr.v4.s_addr);
uint32_t y = ntohl(b->addr.v4.s_addr); uint32_t y = ntohl(b->addr.v4.s_addr);
if ((a->family != AF_INET) || (b->family != AF_INET)) struct cidr *n = cidr_clone(a);
if ((n->family != AF_INET) || (b->family != AF_INET))
return false; return false;
if ((uint32_t)(x + y) < x) if ((uint32_t)(x + y) < x)
@ -124,7 +175,7 @@ static bool cidr_add4(struct cidr *a, struct cidr *b)
return false; return false;
} }
a->addr.v4.s_addr = htonl(x + y); n->addr.v4.s_addr = htonl(x + y);
return true; return true;
} }
@ -133,7 +184,9 @@ static bool cidr_sub4(struct cidr *a, struct cidr *b)
uint32_t x = ntohl(a->addr.v4.s_addr); uint32_t x = ntohl(a->addr.v4.s_addr);
uint32_t y = ntohl(b->addr.v4.s_addr); uint32_t y = ntohl(b->addr.v4.s_addr);
if ((a->family != AF_INET) || (b->family != AF_INET)) struct cidr *n = cidr_clone(a);
if ((n->family != AF_INET) || (b->family != AF_INET))
return false; return false;
if ((uint32_t)(x - y) > x) if ((uint32_t)(x - y) > x)
@ -142,21 +195,27 @@ static bool cidr_sub4(struct cidr *a, struct cidr *b)
return false; return false;
} }
a->addr.v4.s_addr = htonl(x - y); n->addr.v4.s_addr = htonl(x - y);
return true; return true;
} }
static bool cidr_network4(struct cidr *a) static bool cidr_network4(struct cidr *a)
{ {
a->addr.v4.s_addr &= htonl(~((1 << (32 - a->prefix)) - 1)); struct cidr *n = cidr_clone(a);
a->prefix = 32;
n->addr.v4.s_addr &= htonl(~((1 << (32 - n->prefix)) - 1));
n->prefix = 32;
return true; return true;
} }
static bool cidr_broadcast4(struct cidr *a) static bool cidr_broadcast4(struct cidr *a)
{ {
a->addr.v4.s_addr |= htonl(((1 << (32 - a->prefix)) - 1)); struct cidr *n = cidr_clone(a);
a->prefix = 32;
n->addr.v4.s_addr |= htonl(((1 << (32 - n->prefix)) - 1));
n->prefix = 32;
return true; return true;
} }
@ -165,31 +224,24 @@ static bool cidr_contains4(struct cidr *a, struct cidr *b)
uint32_t net1 = a->addr.v4.s_addr & htonl(~((1 << (32 - a->prefix)) - 1)); uint32_t net1 = a->addr.v4.s_addr & htonl(~((1 << (32 - a->prefix)) - 1));
uint32_t net2 = b->addr.v4.s_addr & htonl(~((1 << (32 - a->prefix)) - 1)); uint32_t net2 = b->addr.v4.s_addr & htonl(~((1 << (32 - a->prefix)) - 1));
printed = true;
if ((b->prefix >= a->prefix) && (net1 == net2)) if ((b->prefix >= a->prefix) && (net1 == net2))
{ {
if (!quiet) printf("1\n"); qprintf("1\n");
return true; return true;
} }
else else
{ {
if (!quiet) printf("0\n"); qprintf("0\n");
return false; return false;
} }
} }
static bool cidr_netmask4(struct cidr *a) static bool cidr_netmask4(struct cidr *a)
{ {
struct in_addr mask; struct cidr *n = cidr_clone(a);
char buf[sizeof("255.255.255.255 ")];
mask.s_addr = htonl(~((1 << (32 - a->prefix)) - 1));
if (!quiet) n->addr.v4.s_addr = htonl(~((1 << (32 - n->prefix)) - 1));
printf("%s\n", inet_ntop(AF_INET, &mask, buf, sizeof(buf))); n->prefix = 32;
printed = true;
return true; return true;
} }
@ -198,18 +250,16 @@ static bool cidr_private4(struct cidr *a)
{ {
uint32_t x = ntohl(a->addr.v4.s_addr); uint32_t x = ntohl(a->addr.v4.s_addr);
printed = true;
if (((x >= 0x0A000000) && (x <= 0x0AFFFFFF)) || if (((x >= 0x0A000000) && (x <= 0x0AFFFFFF)) ||
((x >= 0xAC100000) && (x <= 0xAC1FFFFF)) || ((x >= 0xAC100000) && (x <= 0xAC1FFFFF)) ||
((x >= 0xC0A80000) && (x <= 0xC0A8FFFF))) ((x >= 0xC0A80000) && (x <= 0xC0A8FFFF)))
{ {
if (!quiet) printf("1\n"); qprintf("1\n");
return true; return true;
} }
else else
{ {
if (!quiet) printf("0\n"); qprintf("0\n");
return false; return false;
} }
} }
@ -218,40 +268,77 @@ static bool cidr_linklocal4(struct cidr *a)
{ {
uint32_t x = ntohl(a->addr.v4.s_addr); uint32_t x = ntohl(a->addr.v4.s_addr);
printed = true;
if ((x >= 0xA9FE0000) && (x <= 0xA9FEFFFF)) if ((x >= 0xA9FE0000) && (x <= 0xA9FEFFFF))
{ {
if (!quiet) printf("1\n"); qprintf("1\n");
return true; return true;
} }
else else
{ {
if (!quiet) printf("0\n"); qprintf("0\n");
return false; return false;
} }
} }
static bool cidr_prev4(struct cidr *a, struct cidr *b)
{
struct cidr *n = cidr_clone(a);
n->prefix = b->prefix;
n->addr.v4.s_addr -= htonl(1 << (32 - b->prefix));
return true;
}
static bool cidr_next4(struct cidr *a, struct cidr *b)
{
struct cidr *n = cidr_clone(a);
n->prefix = b->prefix;
n->addr.v4.s_addr += htonl(1 << (32 - b->prefix));
return true;
}
static bool cidr_6to4(struct cidr *a)
{
struct cidr *n = cidr_clone(a);
uint32_t x = a->addr.v4.s_addr;
memset(&n->addr.v6.s6_addr, 0, sizeof(n->addr.v6.s6_addr));
n->family = AF_INET6;
n->prefix = 48;
n->addr.v6.s6_addr[0] = 0x20;
n->addr.v6.s6_addr[1] = 0x02;
n->addr.v6.s6_addr[2] = (x >> 24);
n->addr.v6.s6_addr[3] = (x >> 16) & 0xFF;
n->addr.v6.s6_addr[4] = (x >> 8) & 0xFF;
n->addr.v6.s6_addr[5] = x & 0xFF;
return true;
}
static bool cidr_print4(struct cidr *a) static bool cidr_print4(struct cidr *a)
{ {
char *p; char *p;
if (a->family != AF_INET) if (!a || (a->family != AF_INET))
return false; return false;
if (!(p = (char *)inet_ntop(AF_INET, &a->addr.v4, a->buf.v4, sizeof(a->buf.v4)))) if (!(p = (char *)inet_ntop(AF_INET, &a->addr.v4, a->buf.v4, sizeof(a->buf.v4))))
return false; return false;
if (!quiet) if (printed)
printf("%s", p); qprintf(" ");
if (!quiet && (a->prefix < 32)) qprintf("%s", p);
printf("/%u", a->prefix);
if (!quiet) if (a->prefix < 32)
printf("\n"); qprintf("/%u", a->prefix);
printed = true; cidr_pop(a);
return true; return true;
} }
@ -265,11 +352,11 @@ static struct cidr * cidr_parse6(const char *s)
if (!addr || (strlen(s) >= sizeof(addr->buf.v6))) if (!addr || (strlen(s) >= sizeof(addr->buf.v6)))
goto err; goto err;
snprintf(addr->buf.v6, sizeof(addr->buf.v6), "%s", s); snprintf(addr->buf.v4, sizeof(addr->buf.v6), "%s", s);
addr->family = AF_INET6; addr->family = AF_INET6;
if ((p = strchr(addr->buf.v6, '/')) != NULL) if ((p = strchr(addr->buf.v4, '/')) != NULL)
{ {
*p++ = 0; *p++ = 0;
@ -283,9 +370,9 @@ static struct cidr * cidr_parse6(const char *s)
addr->prefix = 128; addr->prefix = 128;
} }
if (p == addr->buf.v6+1) if (p == addr->buf.v4+1)
memset(&addr->addr.v6, 0, sizeof(addr->addr.v6)); memset(&addr->addr.v6, 0, sizeof(addr->addr.v6));
else if (inet_pton(AF_INET6, addr->buf.v6, &addr->addr.v6) != 1) else if (inet_pton(AF_INET6, addr->buf.v4, &addr->addr.v6) != 1)
goto err; goto err;
return addr; return addr;
@ -301,7 +388,8 @@ static bool cidr_add6(struct cidr *a, struct cidr *b)
{ {
uint8_t idx = 15, carry = 0, overflow = 0; uint8_t idx = 15, carry = 0, overflow = 0;
struct in6_addr *x = &a->addr.v6; struct cidr *n = cidr_clone(a);
struct in6_addr *x = &n->addr.v6;
struct in6_addr *y = &b->addr.v6; struct in6_addr *y = &b->addr.v6;
if ((a->family != AF_INET6) || (b->family != AF_INET6)) if ((a->family != AF_INET6) || (b->family != AF_INET6))
@ -327,10 +415,11 @@ static bool cidr_sub6(struct cidr *a, struct cidr *b)
{ {
uint8_t idx = 15, carry = 0, underflow = 0; uint8_t idx = 15, carry = 0, underflow = 0;
struct in6_addr *x = &a->addr.v6; struct cidr *n = cidr_clone(a);
struct in6_addr *x = &n->addr.v6;
struct in6_addr *y = &b->addr.v6; struct in6_addr *y = &b->addr.v6;
if ((a->family != AF_INET6) || (b->family != AF_INET6)) if ((n->family != AF_INET6) || (b->family != AF_INET6))
return false; return false;
do { do {
@ -349,75 +438,134 @@ static bool cidr_sub6(struct cidr *a, struct cidr *b)
return true; return true;
} }
static bool cidr_prev6(struct cidr *a, struct cidr *b)
{
uint8_t idx, carry = 1, underflow = 0;
struct cidr *n = cidr_clone(a);
struct in6_addr *x = &n->addr.v6;
if (b->prefix == 0)
{
fprintf(stderr, "underflow during 'prev'\n");
return false;
}
idx = (b->prefix - 1) / 8;
do {
underflow = !!((x->s6_addr[idx] - carry) < 0);
x->s6_addr[idx] -= carry;
carry = underflow;
}
while (idx-- > 0);
if (carry)
{
fprintf(stderr, "underflow during 'prev'\n");
return false;
}
n->prefix = b->prefix;
return true;
}
static bool cidr_next6(struct cidr *a, struct cidr *b)
{
uint8_t idx, carry = 1, overflow = 0;
struct cidr *n = cidr_clone(a);
struct in6_addr *x = &n->addr.v6;
if (b->prefix == 0)
{
fprintf(stderr, "overflow during 'next'\n");
return false;
}
idx = (b->prefix - 1) / 8;
do {
overflow = !!((x->s6_addr[idx] + carry) >= 256);
x->s6_addr[idx] += carry;
carry = overflow;
}
while (idx-- > 0);
if (carry)
{
fprintf(stderr, "overflow during 'next'\n");
return false;
}
n->prefix = b->prefix;
return true;
}
static bool cidr_network6(struct cidr *a) static bool cidr_network6(struct cidr *a)
{ {
uint8_t i; uint8_t i;
struct cidr *n = cidr_clone(a);
for (i = 0; i < (128 - a->prefix) / 8; i++) for (i = 0; i < (128 - n->prefix) / 8; i++)
a->addr.v6.s6_addr[15-i] = 0; n->addr.v6.s6_addr[15-i] = 0;
if ((128 - a->prefix) % 8) if ((128 - n->prefix) % 8)
a->addr.v6.s6_addr[15-i] &= ~((1 << ((128 - a->prefix) % 8)) - 1); n->addr.v6.s6_addr[15-i] &= ~((1 << ((128 - n->prefix) % 8)) - 1);
return true; return true;
} }
static bool cidr_contains6(struct cidr *a, struct cidr *b) static bool cidr_contains6(struct cidr *a, struct cidr *b)
{ {
struct in6_addr *x = &a->addr.v6; struct cidr *n = cidr_clone(a);
struct in6_addr *x = &n->addr.v6;
struct in6_addr *y = &b->addr.v6; struct in6_addr *y = &b->addr.v6;
uint8_t i = (128 - n->prefix) / 8;
uint8_t i = (128 - a->prefix) / 8; uint8_t m = ~((1 << ((128 - n->prefix) % 8)) - 1);
uint8_t m = ~((1 << ((128 - a->prefix) % 8)) - 1);
uint8_t net1 = x->s6_addr[15-i] & m; uint8_t net1 = x->s6_addr[15-i] & m;
uint8_t net2 = y->s6_addr[15-i] & m; uint8_t net2 = y->s6_addr[15-i] & m;
printed = true; if ((b->prefix >= n->prefix) && (net1 == net2) &&
if ((b->prefix >= a->prefix) && (net1 == net2) &&
((i == 15) || !memcmp(&x->s6_addr, &y->s6_addr, 15-i))) ((i == 15) || !memcmp(&x->s6_addr, &y->s6_addr, 15-i)))
{ {
if (!quiet) printf("1\n"); qprintf("1\n");
return true; return true;
} }
else else
{ {
if (!quiet) printf("0\n"); qprintf("0\n");
return false; return false;
} }
} }
static bool cidr_linklocal6(struct cidr *a) static bool cidr_linklocal6(struct cidr *a)
{ {
printed = true;
if ((a->addr.v6.s6_addr[0] == 0xFE) && if ((a->addr.v6.s6_addr[0] == 0xFE) &&
(a->addr.v6.s6_addr[1] >= 0x80) && (a->addr.v6.s6_addr[1] >= 0x80) &&
(a->addr.v6.s6_addr[1] <= 0xBF)) (a->addr.v6.s6_addr[1] <= 0xBF))
{ {
if (!quiet) printf("1\n"); qprintf("1\n");
return true; return true;
} }
else else
{ {
if (!quiet) printf("0\n"); qprintf("0\n");
return false; return false;
} }
} }
static bool cidr_ula6(struct cidr *a) static bool cidr_ula6(struct cidr *a)
{ {
printed = true;
if ((a->addr.v6.s6_addr[0] >= 0xFC) && if ((a->addr.v6.s6_addr[0] >= 0xFC) &&
(a->addr.v6.s6_addr[0] <= 0xFD)) (a->addr.v6.s6_addr[0] <= 0xFD))
{ {
if (!quiet) printf("1\n"); qprintf("1\n");
return true; return true;
} }
else else
{ {
if (!quiet) printf("0\n"); qprintf("0\n");
return false; return false;
} }
} }
@ -426,22 +574,21 @@ static bool cidr_print6(struct cidr *a)
{ {
char *p; char *p;
if (a->family != AF_INET6) if (!a || (a->family != AF_INET6))
return NULL; return NULL;
if (!(p = (char *)inet_ntop(AF_INET6, &a->addr.v6, a->buf.v6, sizeof(a->buf.v6)))) if (!(p = (char *)inet_ntop(AF_INET6, &a->addr.v6, a->buf.v6, sizeof(a->buf.v6))))
return false; return false;
if (!quiet) if (printed)
printf("%s", p); qprintf(" ");
if (!quiet && (a->prefix < 128)) qprintf("%s", p);
printf("/%u", a->prefix);
if (!quiet) if (a->prefix < 128)
printf("\n"); qprintf("/%u", a->prefix);
printed = true; cidr_pop(a);
return true; return true;
} }
@ -465,13 +612,13 @@ static struct cidr * cidr_parse(const char *op, const char *s, int af_hint)
if (af_hint == AF_INET) if (af_hint == AF_INET)
{ {
a->family = AF_INET; a->family = AF_INET;
a->prefix = 32; a->prefix = sum;
a->addr.v4.s_addr = htonl(sum); a->addr.v4.s_addr = htonl(sum);
} }
else else
{ {
a->family = AF_INET6; a->family = AF_INET6;
a->prefix = 128; a->prefix = sum;
for (i = 0; i <= 15; i++) for (i = 0; i <= 15; i++)
{ {
@ -505,15 +652,10 @@ static struct cidr * cidr_parse(const char *op, const char *s, int af_hint)
static bool cidr_howmany(struct cidr *a, struct cidr *b) static bool cidr_howmany(struct cidr *a, struct cidr *b)
{ {
if (!quiet) if (b->prefix < a->prefix)
{ qprintf("0\n");
if (b->prefix < a->prefix) else
printf("0\n"); qprintf("%u\n", 1 << (b->prefix - a->prefix));
else
printf("%u\n", 1 << (b->prefix - a->prefix));
}
printed = true;
return true; return true;
} }
@ -542,6 +684,16 @@ struct op ops[] = {
.f4.a2 = cidr_sub4, .f4.a2 = cidr_sub4,
.f6.a2 = cidr_sub6 }, .f6.a2 = cidr_sub6 },
{ .name = "next",
.desc = "Advance base address to next prefix of given size",
.f4.a2 = cidr_next4,
.f6.a2 = cidr_next6 },
{ .name = "prev",
.desc = "Lower base address to previous prefix of give size",
.f4.a2 = cidr_prev4,
.f6.a2 = cidr_prev6 },
{ .name = "network", { .name = "network",
.desc = "Turn base address into network address", .desc = "Turn base address into network address",
.f4.a1 = cidr_network4, .f4.a1 = cidr_network4,
@ -557,46 +709,54 @@ struct op ops[] = {
.f6.a2 = cidr_prefix }, .f6.a2 = cidr_prefix },
{ .name = "netmask", { .name = "netmask",
.desc = "Print netmask of base address, does not change base address", .desc = "Calculate netmask of base address",
.f4.a1 = cidr_netmask4 }, .f4.a1 = cidr_netmask4 },
{ .name = "6to4",
.desc = "Calculate 6to4 prefix of given ipv4-address",
.f4.a1 = cidr_6to4 },
{ .name = "howmany", { .name = "howmany",
.desc = "Print amount of righ-hand prefixes that fit into base address, " .desc = "Print amount of righ-hand prefixes that fit into base address",
"does not change base address",
.f4.a2 = cidr_howmany, .f4.a2 = cidr_howmany,
.f6.a2 = cidr_howmany }, .f6.a2 = cidr_howmany },
{ .name = "contains", { .name = "contains",
.desc = "Print '1' if argument fits into base address or '0' " .desc = "Print '1' if argument fits into base address or '0' if not",
"if not, does not change base address",
.f4.a2 = cidr_contains4, .f4.a2 = cidr_contains4,
.f6.a2 = cidr_contains6 }, .f6.a2 = cidr_contains6 },
{ .name = "private", { .name = "private",
.desc = "Print '1' if base address is in RFC1918 private space or '0' " .desc = "Print '1' if base address is in RFC1918 private space or '0' "
"if not, does not change base address", "if not",
.f4.a1 = cidr_private4 }, .f4.a1 = cidr_private4 },
{ .name = "linklocal", { .name = "linklocal",
.desc = "Print '1' if base address is in 169.254.0.0/16 or FE80::/10 " .desc = "Print '1' if base address is in 169.254.0.0/16 or FE80::/10 "
"link local space or '0' if not, does not change base address", "link local space or '0' if not",
.f4.a1 = cidr_linklocal4, .f4.a1 = cidr_linklocal4,
.f6.a1 = cidr_linklocal6 }, .f6.a1 = cidr_linklocal6 },
{ .name = "ula", { .name = "ula",
.desc = "Print '1' if base address is in FC00::/7 unique local address " .desc = "Print '1' if base address is in FC00::/7 unique local address "
"(ULA) space or '0' if not, does not change base address", "(ULA) space or '0' if not",
.f6.a1 = cidr_ula6 }, .f6.a1 = cidr_ula6 },
{ .name = "quiet", { .name = "quiet",
.desc = "Suppress output, useful for test operation where the result can " .desc = "Suppress output, useful for test operation where the result can "
"be inferred from the exit code, does not change base address", "be inferred from the exit code",
.f4.a1 = cidr_quiet, .f4.a1 = cidr_quiet,
.f6.a1 = cidr_quiet }, .f6.a1 = cidr_quiet },
{ .name = "pop",
.desc = "Pop intermediate result from stack",
.f4.a1 = cidr_pop,
.f6.a1 = cidr_pop },
{ .name = "print", { .name = "print",
.desc = "Print intermediate result, invoked implicitely at the end of " .desc = "Print intermediate result and pop it from stack, invoked "
"calculation if no intermediate prints happened", "implicitely at the end of calculation if no intermediate prints "
"happened",
.f4.a1 = cidr_print4, .f4.a1 = cidr_print4,
.f6.a1 = cidr_print6 }, .f6.a1 = cidr_print6 },
}; };
@ -651,11 +811,12 @@ static void usage(const char *prog)
exit(1); exit(1);
} }
static bool runop(struct cidr *a, char ***arg, int *status) static bool runop(char ***arg, int *status)
{ {
int i; int i;
char *arg1 = **arg; char *arg1 = **arg;
char *arg2 = *(*arg+1); char *arg2 = *(*arg+1);
struct cidr *a = stack;
struct cidr *b = NULL; struct cidr *b = NULL;
if (!arg1) if (!arg1)
@ -745,7 +906,9 @@ int main(int argc, char **argv)
if (!a) if (!a)
usage(argv[0]); usage(argv[0]);
while (runop(a, &arg, &status)); cidr_push(a);
while (runop(&arg, &status));
if (*arg) if (*arg)
{ {
@ -755,11 +918,13 @@ int main(int argc, char **argv)
if (!printed && (status < 2)) if (!printed && (status < 2))
{ {
if (a->family == AF_INET) if (stack->family == AF_INET)
cidr_print4(a); cidr_print4(stack);
else else
cidr_print6(a); cidr_print6(stack);
} }
qprintf("\n");
exit(status); exit(status);
} }

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