/* vim: set expandtab ts=4 sw=4: */
/*
* You may redistribute this program and/or modify it under the terms of
* the GNU General Public License as published by the Free Software Foundation,
* either version 3 of the License, or (at your option) any later version.
*
* This program is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with this program. If not, see .
*/
#include "util/AddrTools.h"
#include "util/Bits.h"
#include "util/Endian.h"
#include "util/Hex.h"
#include "util/platform/Sockaddr.h"
#include
/** Takes the path in host byte order. */
void AddrTools_printPath(uint8_t out[20], uint64_t path)
{
uint64_t path_be = Endian_hostToBigEndian64(path);
uint8_t bytes[16];
Hex_encode(bytes, 16, (uint8_t*) &path_be, 8);
out[ 0] = bytes[ 0];
out[ 1] = bytes[ 1];
out[ 2] = bytes[ 2];
out[ 3] = bytes[ 3];
out[ 4] = '.';
out[ 5] = bytes[ 4];
out[ 6] = bytes[ 5];
out[ 7] = bytes[ 6];
out[ 8] = bytes[ 7];
out[ 9] = '.';
out[10] = bytes[ 8];
out[11] = bytes[ 9];
out[12] = bytes[10];
out[13] = bytes[11];
out[14] = '.';
out[15] = bytes[12];
out[16] = bytes[13];
out[17] = bytes[14];
out[18] = bytes[15];
out[19] = '\0';
}
/**
* Parse out a path.
*
* @param out a pointer to a number which will be set to the path in HOST BYTE ORDER.
* @param netAddr a string representation of the path such as "0000.1111.2222.3333" in Big Endian.
* @return 0 if successful, -1 if the netAddr is malformed.
*/
int AddrTools_parsePath(uint64_t* out, const uint8_t netAddr[20])
{
if (netAddr[4] != '.' || netAddr[9] != '.' || netAddr[14] != '.' || netAddr[19] != '\0') {
return -1;
}
uint8_t hex[16] = {
netAddr[ 0],
netAddr[ 1],
netAddr[ 2],
netAddr[ 3],
netAddr[ 5],
netAddr[ 6],
netAddr[ 7],
netAddr[ 8],
netAddr[10],
netAddr[11],
netAddr[12],
netAddr[13],
netAddr[15],
netAddr[16],
netAddr[17],
netAddr[18]
};
uint8_t numberBytes[8];
if (Hex_decode(numberBytes, 8, hex, 16) != 8) {
return -1;
}
uint64_t out_be;
Bits_memcpy(&out_be, numberBytes, 8);
*out = Endian_bigEndianToHost64(out_be);
return 0;
}
void AddrTools_printIp(uint8_t output[40], const uint8_t binIp[16])
{
uint8_t hex[32];
Hex_encode(hex, 32, binIp, 16);
output[ 0] = hex[ 0];
output[ 1] = hex[ 1];
output[ 2] = hex[ 2];
output[ 3] = hex[ 3];
output[ 4] = ':';
output[ 5] = hex[ 4];
output[ 6] = hex[ 5];
output[ 7] = hex[ 6];
output[ 8] = hex[ 7];
output[ 9] = ':';
output[10] = hex[ 8];
output[11] = hex[ 9];
output[12] = hex[10];
output[13] = hex[11];
output[14] = ':';
output[15] = hex[12];
output[16] = hex[13];
output[17] = hex[14];
output[18] = hex[15];
output[19] = ':';
output[20] = hex[16];
output[21] = hex[17];
output[22] = hex[18];
output[23] = hex[19];
output[24] = ':';
output[25] = hex[20];
output[26] = hex[21];
output[27] = hex[22];
output[28] = hex[23];
output[29] = ':';
output[30] = hex[24];
output[31] = hex[25];
output[32] = hex[26];
output[33] = hex[27];
output[34] = ':';
output[35] = hex[28];
output[36] = hex[29];
output[37] = hex[30];
output[38] = hex[31];
output[39] = '\0';
}
void AddrTools_printShortIp(uint8_t output[40], const uint8_t binIp[16])
{
/* The chances of hitting :0:0: and breaking
* RFC5952 are 1 in (1 / (2^16))^2 * 6.
* E. Siler
*/
char *p = output;
int i = 0;
for (; i < 16;) {
if ((size_t)p != (size_t)output) {
*p++= ':';
}
if (binIp[i] > 0x0F) {
Hex_encode(p, 2, &binIp[i++], 1);
p += 2;
} else if (binIp[i] > 0x00) {
*p++ = Hex_encodeLowNibble(binIp[i++]);
} else {
++i;
if (binIp[i] > 0x0F) {
Hex_encode(p, 2, &binIp[i++], 1);
p += 2;
} else {
*p++ = Hex_encodeLowNibble(binIp[i++]);
}
continue;
}
Hex_encode(p, 2, &binIp[i++], 1);
p += 2;
}
*p = '\0';
Assert_true((size_t)p <= ((size_t)output + 40));
Assert_true(i <= 16);
}
/**
* Parse out an address.
*
* @param out a pointer to a byte array which will be set to the bytes of the ipv6 address.
* @param hexAddr a string representation of the ipv6 address such as:
* "fc4f:630d:e499:8f5b:c49f:6e6b:01ae:3120".
* @return 0 if successful, -1 if the hexAddr is malformed.
*/
int AddrTools_parseIp(uint8_t out[16], const uint8_t* hexAddr)
{
struct Sockaddr_storage ss;
if (Sockaddr_parse((const char*) hexAddr, &ss)
|| Sockaddr_getFamily(&ss.addr) != Sockaddr_AF_INET6)
{
return -1;
}
uint8_t* addr = NULL;
Sockaddr_getAddress(&ss.addr, &addr);
Bits_memcpy(out, addr, 16);
return 0;
}
/**
* Parse out an ethernet MAC address.
*
* @param out a pointer to a byte array which will be set to the bytes of the MAC address.
* @param hexAddr a string representation of an ethernet MAC address such as:
* "00:11:22:33:44:55"
* @return 0 if successful, -1 if the hexAddr is malformed.
*/
int AddrTools_parseMac(uint8_t out[6], const uint8_t hexAddr[17])
{
for (int i = 2; i < 15; i += 3) {
if (hexAddr[i] != ':') {
return -1;
}
}
uint8_t hex[12];
int j = 0;
for (int i = 0; i < 18; i++) {
hex[j++] = hexAddr[i++];
hex[j++] = hexAddr[i++];
}
if (Hex_decode(out, 6, hex, 12) != 6) {
return -1;
}
return 0;
}
void AddrTools_printMac(uint8_t output[18], const uint8_t binMac[6])
{
uint8_t hex[12];
Hex_encode(hex, 12, binMac, 6);
output[ 0] = hex[ 0];
output[ 1] = hex[ 1];
output[ 2] = ':';
output[ 3] = hex[ 2];
output[ 4] = hex[ 3];
output[ 5] = ':';
output[ 6] = hex[ 4];
output[ 7] = hex[ 5];
output[ 8] = ':';
output[ 9] = hex[ 6];
output[10] = hex[ 7];
output[11] = ':';
output[12] = hex[ 8];
output[13] = hex[ 9];
output[14] = ':';
output[15] = hex[10];
output[16] = hex[11];
output[17] = '\0';
}