translate.c - platform/external/android-clat - Git at Google

 /*
  * Copyright 2011 Daniel Drown
  *
  * Licensed under the Apache License, Version 2.0 (the "License");
  * you may not use this file except in compliance with the License.
  * You may obtain a copy of the License at
  *
  * http://www.apache.org/licenses/LICENSE-2.0
  *
  * Unless required by applicable law or agreed to in writing, software
  * distributed under the License is distributed on an "AS IS" BASIS,
  * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
  * See the License for the specific language governing permissions and
  * limitations under the License.
  *
  * translate.c - CLAT functions / partial implementation of rfc6145
  */
 #include <string.h>

 #include "netutils/checksum.h"

 #include "clatd.h"
 #include "common.h"
 #include "config.h"
 #include "debug.h"
 #include "icmp.h"
 #include "logging.h"
 #include "translate.h"
 #include "tun.h"

 /* function: packet_checksum
  * calculates the checksum over all the packet components starting from pos
  * checksum - checksum of packet components before pos
  * packet   - packet to calculate the checksum of
  * pos      - position to start counting from
  * returns  - the completed 16-bit checksum, ready to write into a checksum header field
  */
 uint16_t packet_checksum(uint32_t checksum, clat_packet packet, clat_packet_index pos) {
   int i;
   for (i = pos; i < CLAT_POS_MAX; i++) {
     if (packet[i].iov_len > 0) {
       checksum = ip_checksum_add(checksum, packet[i].iov_base, packet[i].iov_len);
     }
   }
   return ip_checksum_finish(checksum);
 }

 /* function: packet_length
  * returns the total length of all the packet components after pos
  * packet - packet to calculate the length of
  * pos    - position to start counting after
  * returns: the total length of the packet components after pos
  */
 uint16_t packet_length(clat_packet packet, clat_packet_index pos) {
   size_t len = 0;
   int i;
   for (i = pos + 1; i < CLAT_POS_MAX; i++) {
     len += packet[i].iov_len;
   }
   return len;
 }

 /* function: is_in_plat_subnet
  * returns true iff the given IPv6 address is in the plat subnet.
  * addr - IPv6 address
  */
 int is_in_plat_subnet(const struct in6_addr *addr6) {
   // Assumes a /96 plat subnet.
   return (addr6 != NULL) && (memcmp(addr6, &Global_Clatd_Config.plat_subnet, 12) == 0);
 }

 /* function: ipv6_addr_to_ipv4_addr
  * return the corresponding ipv4 address for the given ipv6 address
  * addr6 - ipv6 address
  * returns: the IPv4 address
  */
 uint32_t ipv6_addr_to_ipv4_addr(const struct in6_addr *addr6) {
   if (is_in_plat_subnet(addr6)) {
     // Assumes a /96 plat subnet.
     return addr6->s6_addr32[3];
   } else if (IN6_ARE_ADDR_EQUAL(addr6, &Global_Clatd_Config.ipv6_local_subnet)) {
     // Special-case our own address.
     return Global_Clatd_Config.ipv4_local_subnet.s_addr;
   } else {
     // Third party packet. Let the caller deal with it.
     return INADDR_NONE;
   }
 }

 /* function: ipv4_addr_to_ipv6_addr
  * return the corresponding ipv6 address for the given ipv4 address
  * addr4 - ipv4 address
  */
 struct in6_addr ipv4_addr_to_ipv6_addr(uint32_t addr4) {
   struct in6_addr addr6;
   // Both addresses are in network byte order (addr4 comes from a network packet, and the config
   // file entry is read using inet_ntop).
   if (addr4 == Global_Clatd_Config.ipv4_local_subnet.s_addr) {
     return Global_Clatd_Config.ipv6_local_subnet;
   } else {
     // Assumes a /96 plat subnet.
     addr6              = Global_Clatd_Config.plat_subnet;
     addr6.s6_addr32[3] = addr4;
     return addr6;
   }
 }

 /* function: fill_tun_header
  * fill in the header for the tun fd
  * tun_header - tunnel header, already allocated
  * proto      - ethernet protocol id: ETH_P_IP(ipv4) or ETH_P_IPV6(ipv6)
  */
 void fill_tun_header(struct tun_pi *tun_header, uint16_t proto) {
   tun_header->flags = 0;
   tun_header->proto = htons(proto);
 }

 /* function: fill_ip_header
  * generate an ipv4 header from an ipv6 header
  * ip_targ     - (ipv4) target packet header, source: original ipv4 addr, dest: local subnet addr
  * payload_len - length of other data inside packet
  * protocol    - protocol number (tcp, udp, etc)
  * old_header  - (ipv6) source packet header, source: nat64 prefix, dest: local subnet prefix
  */
 void fill_ip_header(struct iphdr *ip, uint16_t payload_len, uint8_t protocol,
                     const struct ip6_hdr *old_header) {
   int ttl_guess;
   memset(ip, 0, sizeof(struct iphdr));

   ip->ihl      = 5;
   ip->version  = 4;
   ip->tos      = 0;
   ip->tot_len  = htons(sizeof(struct iphdr) + payload_len);
   ip->id       = 0;
   ip->frag_off = htons(IP_DF);
   ip->ttl      = old_header->ip6_hlim;
   ip->protocol = protocol;
   ip->check    = 0;

   ip->saddr = ipv6_addr_to_ipv4_addr(&old_header->ip6_src);
   ip->daddr = ipv6_addr_to_ipv4_addr(&old_header->ip6_dst);

   // Third-party ICMPv6 message. This may have been originated by an native IPv6 address.
   // In that case, the source IPv6 address can't be translated and we need to make up an IPv4
   // source address. For now, use 255.0.0.<ttl>, which at least looks useful in traceroute.
   if ((uint32_t)ip->saddr == INADDR_NONE) {
     ttl_guess = icmp_guess_ttl(old_header->ip6_hlim);
     ip->saddr = htonl((0xff << 24) + ttl_guess);
   }
 }

 /* function: fill_ip6_header
  * generate an ipv6 header from an ipv4 header
  * ip6         - (ipv6) target packet header, source: local subnet prefix, dest: nat64 prefix
  * payload_len - length of other data inside packet
  * protocol    - protocol number (tcp, udp, etc)
  * old_header  - (ipv4) source packet header, source: local subnet addr, dest: internet's ipv4 addr
  */
 void fill_ip6_header(struct ip6_hdr *ip6, uint16_t payload_len, uint8_t protocol,
                      const struct iphdr *old_header) {
   memset(ip6, 0, sizeof(struct ip6_hdr));

   ip6->ip6_vfc  = 6 << 4;
   ip6->ip6_plen = htons(payload_len);
   ip6->ip6_nxt  = protocol;
   ip6->ip6_hlim = old_header->ttl;

   ip6->ip6_src = ipv4_addr_to_ipv6_addr(old_header->saddr);
   ip6->ip6_dst = ipv4_addr_to_ipv6_addr(old_header->daddr);
 }

 /* function: maybe_fill_frag_header
  * fills a fragmentation header
  * generate an ipv6 fragment header from an ipv4 header
  * frag_hdr    - target (ipv6) fragmentation header
  * ip6_targ    - target (ipv6) header
  * old_header  - (ipv4) source packet header
  * returns: the length of the fragmentation header if present, or zero if not present
  */
 size_t maybe_fill_frag_header(struct ip6_frag *frag_hdr, struct ip6_hdr *ip6_targ,
                               const struct iphdr *old_header) {
   uint16_t frag_flags = ntohs(old_header->frag_off);
   uint16_t frag_off   = frag_flags & IP_OFFMASK;
   if (frag_off == 0 && (frag_flags & IP_MF) == 0) {
     // Not a fragment.
     return 0;
   }

   frag_hdr->ip6f_nxt      = ip6_targ->ip6_nxt;
   frag_hdr->ip6f_reserved = 0;
   // In IPv4, the offset is the bottom 13 bits; in IPv6 it's the top 13 bits.
   frag_hdr->ip6f_offlg = htons(frag_off << 3);
   if (frag_flags & IP_MF) {
     frag_hdr->ip6f_offlg |= IP6F_MORE_FRAG;
   }
   frag_hdr->ip6f_ident = htonl(ntohs(old_header->id));
   ip6_targ->ip6_nxt    = IPPROTO_FRAGMENT;

   return sizeof(*frag_hdr);
 }

 /* function: parse_frag_header
  * return the length of the fragmentation header if present, or zero if not present
  * generate an ipv6 fragment header from an ipv4 header
  * frag_hdr    - (ipv6) fragmentation header
  * ip_targ     - target (ipv4) header
  * returns: the next header value
  */
 uint8_t parse_frag_header(const struct ip6_frag *frag_hdr, struct iphdr *ip_targ) {
   uint16_t frag_off = (ntohs(frag_hdr->ip6f_offlg & IP6F_OFF_MASK) >> 3);
   if (frag_hdr->ip6f_offlg & IP6F_MORE_FRAG) {
     frag_off |= IP_MF;
   }
   ip_targ->frag_off = htons(frag_off);
   ip_targ->id       = htons(ntohl(frag_hdr->ip6f_ident) & 0xffff);
   ip_targ->protocol = frag_hdr->ip6f_nxt;
   return frag_hdr->ip6f_nxt;
 }

 /* function: icmp_to_icmp6
  * translate ipv4 icmp to ipv6 icmp
  * out          - output packet
  * icmp         - source packet icmp header
  * checksum     - pseudo-header checksum
  * payload      - icmp payload
  * payload_size - size of payload
  * returns: the highest position in the output clat_packet that's filled in
  */
 int icmp_to_icmp6(clat_packet out, clat_packet_index pos, const struct icmphdr *icmp,
                   uint32_t checksum, const uint8_t *payload, size_t payload_size) {
   struct icmp6_hdr *icmp6_targ = out[pos].iov_base;
   uint8_t icmp6_type;
   int clat_packet_len;

   memset(icmp6_targ, 0, sizeof(struct icmp6_hdr));

   icmp6_type             = icmp_to_icmp6_type(icmp->type, icmp->code);
   icmp6_targ->icmp6_type = icmp6_type;
   icmp6_targ->icmp6_code = icmp_to_icmp6_code(icmp->type, icmp->code);

   out[pos].iov_len = sizeof(struct icmp6_hdr);

   if (pos == CLAT_POS_TRANSPORTHDR && is_icmp_error(icmp->type) && icmp6_type != ICMP6_PARAM_PROB) {
     // An ICMP error we understand, one level deep.
     // Translate the nested packet (the one that caused the error).
     clat_packet_len = ipv4_packet(out, pos + 1, payload, payload_size);

     // The pseudo-header checksum was calculated on the transport length of the original IPv4
     // packet that we were asked to translate. This transport length is 20 bytes smaller than it
     // needs to be, because the ICMP error contains an IPv4 header, which we will be translating to
     // an IPv6 header, which is 20 bytes longer. Fix it up here.
     // We only need to do this for ICMP->ICMPv6, not ICMPv6->ICMP, because ICMP does not use the
     // pseudo-header when calculating its checksum (as the IPv4 header has its own checksum).
     checksum = checksum + htons(20);
   } else if (icmp6_type == ICMP6_ECHO_REQUEST || icmp6_type == ICMP6_ECHO_REPLY) {
     // Ping packet.
     icmp6_targ->icmp6_id           = icmp->un.echo.id;
     icmp6_targ->icmp6_seq          = icmp->un.echo.sequence;
     out[CLAT_POS_PAYLOAD].iov_base = (uint8_t *)payload;
     out[CLAT_POS_PAYLOAD].iov_len  = payload_size;
     clat_packet_len                = CLAT_POS_PAYLOAD + 1;
   } else {
     // Unknown type/code. The type/code conversion functions have already logged an error.
     return 0;
   }

   icmp6_targ->icmp6_cksum = 0;  // Checksum field must be 0 when calculating checksum.
   icmp6_targ->icmp6_cksum = packet_checksum(checksum, out, pos);

   return clat_packet_len;
 }

 /* function: icmp6_to_icmp
  * translate ipv6 icmp to ipv4 icmp
  * out          - output packet
  * icmp6        - source packet icmp6 header
  * payload      - icmp6 payload
  * payload_size - size of payload
  * returns: the highest position in the output clat_packet that's filled in
  */
 int icmp6_to_icmp(clat_packet out, clat_packet_index pos, const struct icmp6_hdr *icmp6,
                   const uint8_t *payload, size_t payload_size) {
   struct icmphdr *icmp_targ = out[pos].iov_base;
   uint8_t icmp_type;
   int clat_packet_len;

   memset(icmp_targ, 0, sizeof(struct icmphdr));

   icmp_type       = icmp6_to_icmp_type(icmp6->icmp6_type, icmp6->icmp6_code);
   icmp_targ->type = icmp_type;
   icmp_targ->code = icmp6_to_icmp_code(icmp6->icmp6_type, icmp6->icmp6_code);

   out[pos].iov_len = sizeof(struct icmphdr);

   if (pos == CLAT_POS_TRANSPORTHDR && is_icmp6_error(icmp6->icmp6_type) &&
       icmp_type != ICMP_PARAMETERPROB) {
     // An ICMPv6 error we understand, one level deep.
     // Translate the nested packet (the one that caused the error).
     clat_packet_len = ipv6_packet(out, pos + 1, payload, payload_size);
   } else if (icmp_type == ICMP_ECHO || icmp_type == ICMP_ECHOREPLY) {
     // Ping packet.
     icmp_targ->un.echo.id          = icmp6->icmp6_id;
     icmp_targ->un.echo.sequence    = icmp6->icmp6_seq;
     out[CLAT_POS_PAYLOAD].iov_base = (uint8_t *)payload;
     out[CLAT_POS_PAYLOAD].iov_len  = payload_size;
     clat_packet_len                = CLAT_POS_PAYLOAD + 1;
   } else {
     // Unknown type/code. The type/code conversion functions have already logged an error.
     return 0;
   }

   icmp_targ->checksum = 0;  // Checksum field must be 0 when calculating checksum.
   icmp_targ->checksum = packet_checksum(0, out, pos);

   return clat_packet_len;
 }

 /* function: generic_packet
  * takes a generic IP packet and sets it up for translation
  * out      - output packet
  * pos      - position in the output packet of the transport header
  * payload  - pointer to IP payload
  * len      - size of ip payload
  * returns: the highest position in the output clat_packet that's filled in
  */
 int generic_packet(clat_packet out, clat_packet_index pos, const uint8_t *payload, size_t len) {
   out[pos].iov_len               = 0;
   out[CLAT_POS_PAYLOAD].iov_base = (uint8_t *)payload;
   out[CLAT_POS_PAYLOAD].iov_len  = len;

   return CLAT_POS_PAYLOAD + 1;
 }

 /* function: udp_packet
  * takes a udp packet and sets it up for translation
  * out      - output packet
  * udp      - pointer to udp header in packet
  * old_sum  - pseudo-header checksum of old header
  * new_sum  - pseudo-header checksum of new header
  * len      - size of ip payload
  */
 int udp_packet(clat_packet out, clat_packet_index pos, const struct udphdr *udp, uint32_t old_sum,
                uint32_t new_sum, size_t len) {
   const uint8_t *payload;
   size_t payload_size;

   if (len < sizeof(struct udphdr)) {
     logmsg_dbg(ANDROID_LOG_ERROR, "udp_packet/(too small)");
     return 0;
   }

   payload      = (const uint8_t *)(udp + 1);
   payload_size = len - sizeof(struct udphdr);

   return udp_translate(out, pos, udp, old_sum, new_sum, payload, payload_size);
 }

 /* function: tcp_packet
  * takes a tcp packet and sets it up for translation
  * out      - output packet
  * tcp      - pointer to tcp header in packet
  * checksum - pseudo-header checksum
  * len      - size of ip payload
  * returns: the highest position in the output clat_packet that's filled in
  */
 int tcp_packet(clat_packet out, clat_packet_index pos, const struct tcphdr *tcp, uint32_t old_sum,
                uint32_t new_sum, size_t len) {
   const uint8_t *payload;
   size_t payload_size, header_size;

   if (len < sizeof(struct tcphdr)) {
     logmsg_dbg(ANDROID_LOG_ERROR, "tcp_packet/(too small)");
     return 0;
   }

   if (tcp->doff < 5) {
     logmsg_dbg(ANDROID_LOG_ERROR, "tcp_packet/tcp header length set to less than 5: %x", tcp->doff);
     return 0;
   }

   if ((size_t)tcp->doff * 4 > len) {
     logmsg_dbg(ANDROID_LOG_ERROR, "tcp_packet/tcp header length set too large: %x", tcp->doff);
     return 0;
   }

   header_size  = tcp->doff * 4;
   payload      = ((const uint8_t *)tcp) + header_size;
   payload_size = len - header_size;

   return tcp_translate(out, pos, tcp, header_size, old_sum, new_sum, payload, payload_size);
 }

 /* function: udp_translate
  * common between ipv4/ipv6 - setup checksum and send udp packet
  * out          - output packet
  * udp          - udp header
  * old_sum      - pseudo-header checksum of old header
  * new_sum      - pseudo-header checksum of new header
  * payload      - tcp payload
  * payload_size - size of payload
  * returns: the highest position in the output clat_packet that's filled in
  */
 int udp_translate(clat_packet out, clat_packet_index pos, const struct udphdr *udp,
                   uint32_t old_sum, uint32_t new_sum, const uint8_t *payload, size_t payload_size) {
   struct udphdr *udp_targ = out[pos].iov_base;

   memcpy(udp_targ, udp, sizeof(struct udphdr));

   out[pos].iov_len               = sizeof(struct udphdr);
   out[CLAT_POS_PAYLOAD].iov_base = (uint8_t *)payload;
   out[CLAT_POS_PAYLOAD].iov_len  = payload_size;

   if (udp_targ->check) {
     udp_targ->check = ip_checksum_adjust(udp->check, old_sum, new_sum);
   } else {
     // Zero checksums are special. RFC 768 says, "An all zero transmitted checksum value means that
     // the transmitter generated no checksum (for debugging or for higher level protocols that
     // don't care)." However, in IPv6 zero UDP checksums were only permitted by RFC 6935 (2013). So
     // for safety we recompute it.
     udp_targ->check = 0;  // Checksum field must be 0 when calculating checksum.
     udp_targ->check = packet_checksum(new_sum, out, pos);
   }

   // RFC 768: "If the computed checksum is zero, it is transmitted as all ones (the equivalent
   // in one's complement arithmetic)."
   if (!udp_targ->check) {
     udp_targ->check = 0xffff;
   }

   return CLAT_POS_PAYLOAD + 1;
 }

 /* function: tcp_translate
  * common between ipv4/ipv6 - setup checksum and send tcp packet
  * out          - output packet
  * tcp          - tcp header
  * header_size  - size of tcp header including options
  * checksum     - partial checksum covering ipv4/ipv6 header
  * payload      - tcp payload
  * payload_size - size of payload
  * returns: the highest position in the output clat_packet that's filled in
  */
 int tcp_translate(clat_packet out, clat_packet_index pos, const struct tcphdr *tcp,
                   size_t header_size, uint32_t old_sum, uint32_t new_sum, const uint8_t *payload,
                   size_t payload_size) {
   struct tcphdr *tcp_targ = out[pos].iov_base;
   out[pos].iov_len        = header_size;

   if (header_size > MAX_TCP_HDR) {
     // A TCP header cannot be more than MAX_TCP_HDR bytes long because it's a 4-bit field that
     // counts in 4-byte words. So this can never happen unless there is a bug in the caller.
     logmsg(ANDROID_LOG_ERROR, "tcp_translate: header too long %d > %d, truncating", header_size,
            MAX_TCP_HDR);
     header_size = MAX_TCP_HDR;
   }

   memcpy(tcp_targ, tcp, header_size);

   out[CLAT_POS_PAYLOAD].iov_base = (uint8_t *)payload;
   out[CLAT_POS_PAYLOAD].iov_len  = payload_size;

   tcp_targ->check = ip_checksum_adjust(tcp->check, old_sum, new_sum);

   return CLAT_POS_PAYLOAD + 1;
 }

 // Weak symbol so we can override it in the unit test.
 void send_rawv6(int fd, clat_packet out, int iov_len) __attribute__((weak));

 void send_rawv6(int fd, clat_packet out, int iov_len) {
   // A send on a raw socket requires a destination address to be specified even if the socket's
   // protocol is IPPROTO_RAW. This is the address that will be used in routing lookups; the
   // destination address in the packet header only affects what appears on the wire, not where the
   // packet is sent to.
   static struct sockaddr_in6 sin6 = { AF_INET6, 0, 0, { { { 0, 0, 0, 0 } } }, 0 };
   static struct msghdr msg        = {
     .msg_name    = &sin6,
     .msg_namelen = sizeof(sin6),
   };

   msg.msg_iov = out, msg.msg_iovlen = iov_len,
   sin6.sin6_addr = ((struct ip6_hdr *)out[CLAT_POS_IPHDR].iov_base)->ip6_dst;
   sendmsg(fd, &msg, 0);
 }

 /* function: translate_packet
  * takes a packet, translates it, and writes it to fd
  * fd         - fd to write translated packet to
  * to_ipv6    - true if translating to ipv6, false if translating to ipv4
  * packet     - packet
  * packetsize - size of packet
  */
 void translate_packet(int fd, int to_ipv6, const uint8_t *packet, size_t packetsize) {
   int iov_len = 0;

   // Allocate buffers for all packet headers.
   struct tun_pi tun_targ;
   char iphdr[sizeof(struct ip6_hdr)];
   char fraghdr[sizeof(struct ip6_frag)];
   char transporthdr[MAX_TCP_HDR];
   char icmp_iphdr[sizeof(struct ip6_hdr)];
   char icmp_fraghdr[sizeof(struct ip6_frag)];
   char icmp_transporthdr[MAX_TCP_HDR];

   // iovec of the packets we'll send. This gets passed down to the translation functions.
   clat_packet out = {
     { &tun_targ, 0 },          // Tunnel header.
     { iphdr, 0 },              // IP header.
     { fraghdr, 0 },            // Fragment header.
     { transporthdr, 0 },       // Transport layer header.
     { icmp_iphdr, 0 },         // ICMP error inner IP header.
     { icmp_fraghdr, 0 },       // ICMP error fragmentation header.
     { icmp_transporthdr, 0 },  // ICMP error transport layer header.
     { NULL, 0 },               // Payload. No buffer, it's a pointer to the original payload.
   };

   if (to_ipv6) {
     iov_len = ipv4_packet(out, CLAT_POS_IPHDR, packet, packetsize);
     if (iov_len > 0) {
       send_rawv6(fd, out, iov_len);
     }
   } else {
     iov_len = ipv6_packet(out, CLAT_POS_IPHDR, packet, packetsize);
     if (iov_len > 0) {
       fill_tun_header(&tun_targ, ETH_P_IP);
       out[CLAT_POS_TUNHDR].iov_len = sizeof(tun_targ);
       send_tun(fd, out, iov_len);
     }
   }
 }
	/*
	* Copyright 2011 Daniel Drown
	*
	* Licensed under the Apache License, Version 2.0 (the "License");
	* you may not use this file except in compliance with the License.
	* You may obtain a copy of the License at
	*
	* http://www.apache.org/licenses/LICENSE-2.0
	*
	* Unless required by applicable law or agreed to in writing, software
	* distributed under the License is distributed on an "AS IS" BASIS,
	* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
	* See the License for the specific language governing permissions and
	* limitations under the License.
	*
	* translate.c - CLAT functions / partial implementation of rfc6145
	*/
	#include <string.h>

	#include "netutils/checksum.h"

	#include "clatd.h"
	#include "common.h"
	#include "config.h"
	#include "debug.h"
	#include "icmp.h"
	#include "logging.h"
	#include "translate.h"
	#include "tun.h"

	/* function: packet_checksum
	* calculates the checksum over all the packet components starting from pos
	* checksum - checksum of packet components before pos
	* packet - packet to calculate the checksum of
	* pos - position to start counting from
	* returns - the completed 16-bit checksum, ready to write into a checksum header field
	*/
	uint16_t packet_checksum(uint32_t checksum, clat_packet packet, clat_packet_index pos) {
	int i;
	for (i = pos; i < CLAT_POS_MAX; i++) {
	if (packet[i].iov_len > 0) {
	checksum = ip_checksum_add(checksum, packet[i].iov_base, packet[i].iov_len);
	}
	}
	return ip_checksum_finish(checksum);
	}

	/* function: packet_length
	* returns the total length of all the packet components after pos
	* packet - packet to calculate the length of
	* pos - position to start counting after
	* returns: the total length of the packet components after pos
	*/
	uint16_t packet_length(clat_packet packet, clat_packet_index pos) {
	size_t len = 0;
	int i;
	for (i = pos + 1; i < CLAT_POS_MAX; i++) {
	len += packet[i].iov_len;
	}
	return len;
	}

	/* function: is_in_plat_subnet
	* returns true iff the given IPv6 address is in the plat subnet.
	* addr - IPv6 address
	*/
	int is_in_plat_subnet(const struct in6_addr *addr6) {
	// Assumes a /96 plat subnet.
	return (addr6 != NULL) && (memcmp(addr6, &Global_Clatd_Config.plat_subnet, 12) == 0);
	}

	/* function: ipv6_addr_to_ipv4_addr
	* return the corresponding ipv4 address for the given ipv6 address
	* addr6 - ipv6 address
	* returns: the IPv4 address
	*/
	uint32_t ipv6_addr_to_ipv4_addr(const struct in6_addr *addr6) {
	if (is_in_plat_subnet(addr6)) {
	// Assumes a /96 plat subnet.
	return addr6->s6_addr32[3];
	} else if (IN6_ARE_ADDR_EQUAL(addr6, &Global_Clatd_Config.ipv6_local_subnet)) {
	// Special-case our own address.
	return Global_Clatd_Config.ipv4_local_subnet.s_addr;
	} else {
	// Third party packet. Let the caller deal with it.
	return INADDR_NONE;
	}
	}

	/* function: ipv4_addr_to_ipv6_addr
	* return the corresponding ipv6 address for the given ipv4 address
	* addr4 - ipv4 address
	*/
	struct in6_addr ipv4_addr_to_ipv6_addr(uint32_t addr4) {
	struct in6_addr addr6;
	// Both addresses are in network byte order (addr4 comes from a network packet, and the config
	// file entry is read using inet_ntop).
	if (addr4 == Global_Clatd_Config.ipv4_local_subnet.s_addr) {
	return Global_Clatd_Config.ipv6_local_subnet;
	} else {
	// Assumes a /96 plat subnet.
	addr6 = Global_Clatd_Config.plat_subnet;
	addr6.s6_addr32[3] = addr4;
	return addr6;
	}
	}

	/* function: fill_tun_header
	* fill in the header for the tun fd
	* tun_header - tunnel header, already allocated
	* proto - ethernet protocol id: ETH_P_IP(ipv4) or ETH_P_IPV6(ipv6)
	*/
	void fill_tun_header(struct tun_pi *tun_header, uint16_t proto) {
	tun_header->flags = 0;
	tun_header->proto = htons(proto);
	}

	/* function: fill_ip_header
	* generate an ipv4 header from an ipv6 header
	* ip_targ - (ipv4) target packet header, source: original ipv4 addr, dest: local subnet addr
	* payload_len - length of other data inside packet
	* protocol - protocol number (tcp, udp, etc)
	* old_header - (ipv6) source packet header, source: nat64 prefix, dest: local subnet prefix
	*/
	void fill_ip_header(struct iphdr *ip, uint16_t payload_len, uint8_t protocol,
	const struct ip6_hdr *old_header) {
	int ttl_guess;
	memset(ip, 0, sizeof(struct iphdr));

	ip->ihl = 5;
	ip->version = 4;
	ip->tos = 0;
	ip->tot_len = htons(sizeof(struct iphdr) + payload_len);
	ip->id = 0;
	ip->frag_off = htons(IP_DF);
	ip->ttl = old_header->ip6_hlim;
	ip->protocol = protocol;
	ip->check = 0;

	ip->saddr = ipv6_addr_to_ipv4_addr(&old_header->ip6_src);
	ip->daddr = ipv6_addr_to_ipv4_addr(&old_header->ip6_dst);

	// Third-party ICMPv6 message. This may have been originated by an native IPv6 address.
	// In that case, the source IPv6 address can't be translated and we need to make up an IPv4
	// source address. For now, use 255.0.0.<ttl>, which at least looks useful in traceroute.
	if ((uint32_t)ip->saddr == INADDR_NONE) {
	ttl_guess = icmp_guess_ttl(old_header->ip6_hlim);
	ip->saddr = htonl((0xff << 24) + ttl_guess);
	}
	}

	/* function: fill_ip6_header
	* generate an ipv6 header from an ipv4 header
	* ip6 - (ipv6) target packet header, source: local subnet prefix, dest: nat64 prefix
	* payload_len - length of other data inside packet
	* protocol - protocol number (tcp, udp, etc)
	* old_header - (ipv4) source packet header, source: local subnet addr, dest: internet's ipv4 addr
	*/
	void fill_ip6_header(struct ip6_hdr *ip6, uint16_t payload_len, uint8_t protocol,
	const struct iphdr *old_header) {
	memset(ip6, 0, sizeof(struct ip6_hdr));

	ip6->ip6_vfc = 6 << 4;
	ip6->ip6_plen = htons(payload_len);
	ip6->ip6_nxt = protocol;
	ip6->ip6_hlim = old_header->ttl;

	ip6->ip6_src = ipv4_addr_to_ipv6_addr(old_header->saddr);
	ip6->ip6_dst = ipv4_addr_to_ipv6_addr(old_header->daddr);
	}

	/* function: maybe_fill_frag_header
	* fills a fragmentation header
	* generate an ipv6 fragment header from an ipv4 header
	* frag_hdr - target (ipv6) fragmentation header
	* ip6_targ - target (ipv6) header
	* old_header - (ipv4) source packet header
	* returns: the length of the fragmentation header if present, or zero if not present
	*/
	size_t maybe_fill_frag_header(struct ip6_frag frag_hdr, struct ip6_hdr ip6_targ,
	const struct iphdr *old_header) {
	uint16_t frag_flags = ntohs(old_header->frag_off);
	uint16_t frag_off = frag_flags & IP_OFFMASK;
	if (frag_off == 0 && (frag_flags & IP_MF) == 0) {
	// Not a fragment.
	return 0;
	}

	frag_hdr->ip6f_nxt = ip6_targ->ip6_nxt;
	frag_hdr->ip6f_reserved = 0;
	// In IPv4, the offset is the bottom 13 bits; in IPv6 it's the top 13 bits.
	frag_hdr->ip6f_offlg = htons(frag_off << 3);
	if (frag_flags & IP_MF) {
	frag_hdr->ip6f_offlg \|= IP6F_MORE_FRAG;
	}
	frag_hdr->ip6f_ident = htonl(ntohs(old_header->id));
	ip6_targ->ip6_nxt = IPPROTO_FRAGMENT;

	return sizeof(*frag_hdr);
	}

	/* function: parse_frag_header
	* return the length of the fragmentation header if present, or zero if not present
	* generate an ipv6 fragment header from an ipv4 header
	* frag_hdr - (ipv6) fragmentation header
	* ip_targ - target (ipv4) header
	* returns: the next header value
	*/
	uint8_t parse_frag_header(const struct ip6_frag frag_hdr, struct iphdr ip_targ) {
	uint16_t frag_off = (ntohs(frag_hdr->ip6f_offlg & IP6F_OFF_MASK) >> 3);
	if (frag_hdr->ip6f_offlg & IP6F_MORE_FRAG) {
	frag_off \|= IP_MF;
	}
	ip_targ->frag_off = htons(frag_off);
	ip_targ->id = htons(ntohl(frag_hdr->ip6f_ident) & 0xffff);
	ip_targ->protocol = frag_hdr->ip6f_nxt;
	return frag_hdr->ip6f_nxt;
	}

	/* function: icmp_to_icmp6
	* translate ipv4 icmp to ipv6 icmp
	* out - output packet
	* icmp - source packet icmp header
	* checksum - pseudo-header checksum
	* payload - icmp payload
	* payload_size - size of payload
	* returns: the highest position in the output clat_packet that's filled in
	*/
	int icmp_to_icmp6(clat_packet out, clat_packet_index pos, const struct icmphdr *icmp,
	uint32_t checksum, const uint8_t *payload, size_t payload_size) {
	struct icmp6_hdr *icmp6_targ = out[pos].iov_base;
	uint8_t icmp6_type;
	int clat_packet_len;

	memset(icmp6_targ, 0, sizeof(struct icmp6_hdr));

	icmp6_type = icmp_to_icmp6_type(icmp->type, icmp->code);
	icmp6_targ->icmp6_type = icmp6_type;
	icmp6_targ->icmp6_code = icmp_to_icmp6_code(icmp->type, icmp->code);

	out[pos].iov_len = sizeof(struct icmp6_hdr);

	if (pos == CLAT_POS_TRANSPORTHDR && is_icmp_error(icmp->type) && icmp6_type != ICMP6_PARAM_PROB) {
	// An ICMP error we understand, one level deep.
	// Translate the nested packet (the one that caused the error).
	clat_packet_len = ipv4_packet(out, pos + 1, payload, payload_size);

	// The pseudo-header checksum was calculated on the transport length of the original IPv4
	// packet that we were asked to translate. This transport length is 20 bytes smaller than it
	// needs to be, because the ICMP error contains an IPv4 header, which we will be translating to
	// an IPv6 header, which is 20 bytes longer. Fix it up here.
	// We only need to do this for ICMP->ICMPv6, not ICMPv6->ICMP, because ICMP does not use the
	// pseudo-header when calculating its checksum (as the IPv4 header has its own checksum).
	checksum = checksum + htons(20);
	} else if (icmp6_type == ICMP6_ECHO_REQUEST \|\| icmp6_type == ICMP6_ECHO_REPLY) {
	// Ping packet.
	icmp6_targ->icmp6_id = icmp->un.echo.id;
	icmp6_targ->icmp6_seq = icmp->un.echo.sequence;
	out[CLAT_POS_PAYLOAD].iov_base = (uint8_t *)payload;
	out[CLAT_POS_PAYLOAD].iov_len = payload_size;
	clat_packet_len = CLAT_POS_PAYLOAD + 1;
	} else {
	// Unknown type/code. The type/code conversion functions have already logged an error.
	return 0;
	}

	icmp6_targ->icmp6_cksum = 0; // Checksum field must be 0 when calculating checksum.
	icmp6_targ->icmp6_cksum = packet_checksum(checksum, out, pos);

	return clat_packet_len;
	}

	/* function: icmp6_to_icmp
	* translate ipv6 icmp to ipv4 icmp
	* out - output packet
	* icmp6 - source packet icmp6 header
	* payload - icmp6 payload
	* payload_size - size of payload
	* returns: the highest position in the output clat_packet that's filled in
	*/
	int icmp6_to_icmp(clat_packet out, clat_packet_index pos, const struct icmp6_hdr *icmp6,
	const uint8_t *payload, size_t payload_size) {
	struct icmphdr *icmp_targ = out[pos].iov_base;
	uint8_t icmp_type;
	int clat_packet_len;

	memset(icmp_targ, 0, sizeof(struct icmphdr));

	icmp_type = icmp6_to_icmp_type(icmp6->icmp6_type, icmp6->icmp6_code);
	icmp_targ->type = icmp_type;
	icmp_targ->code = icmp6_to_icmp_code(icmp6->icmp6_type, icmp6->icmp6_code);

	out[pos].iov_len = sizeof(struct icmphdr);

	if (pos == CLAT_POS_TRANSPORTHDR && is_icmp6_error(icmp6->icmp6_type) &&
	icmp_type != ICMP_PARAMETERPROB) {
	// An ICMPv6 error we understand, one level deep.
	// Translate the nested packet (the one that caused the error).
	clat_packet_len = ipv6_packet(out, pos + 1, payload, payload_size);
	} else if (icmp_type == ICMP_ECHO \|\| icmp_type == ICMP_ECHOREPLY) {
	// Ping packet.
	icmp_targ->un.echo.id = icmp6->icmp6_id;
	icmp_targ->un.echo.sequence = icmp6->icmp6_seq;
	out[CLAT_POS_PAYLOAD].iov_base = (uint8_t *)payload;
	out[CLAT_POS_PAYLOAD].iov_len = payload_size;
	clat_packet_len = CLAT_POS_PAYLOAD + 1;
	} else {
	// Unknown type/code. The type/code conversion functions have already logged an error.
	return 0;
	}

	icmp_targ->checksum = 0; // Checksum field must be 0 when calculating checksum.
	icmp_targ->checksum = packet_checksum(0, out, pos);

	return clat_packet_len;
	}

	/* function: generic_packet
	* takes a generic IP packet and sets it up for translation
	* out - output packet
	* pos - position in the output packet of the transport header
	* payload - pointer to IP payload
	* len - size of ip payload
	* returns: the highest position in the output clat_packet that's filled in
	*/
	int generic_packet(clat_packet out, clat_packet_index pos, const uint8_t *payload, size_t len) {
	out[pos].iov_len = 0;
	out[CLAT_POS_PAYLOAD].iov_base = (uint8_t *)payload;
	out[CLAT_POS_PAYLOAD].iov_len = len;

	return CLAT_POS_PAYLOAD + 1;
	}

	/* function: udp_packet
	* takes a udp packet and sets it up for translation
	* out - output packet
	* udp - pointer to udp header in packet
	* old_sum - pseudo-header checksum of old header
	* new_sum - pseudo-header checksum of new header
	* len - size of ip payload
	*/
	int udp_packet(clat_packet out, clat_packet_index pos, const struct udphdr *udp, uint32_t old_sum,
	uint32_t new_sum, size_t len) {
	const uint8_t *payload;
	size_t payload_size;

	if (len < sizeof(struct udphdr)) {
	logmsg_dbg(ANDROID_LOG_ERROR, "udp_packet/(too small)");
	return 0;
	}

	payload = (const uint8_t *)(udp + 1);
	payload_size = len - sizeof(struct udphdr);

	return udp_translate(out, pos, udp, old_sum, new_sum, payload, payload_size);
	}

	/* function: tcp_packet
	* takes a tcp packet and sets it up for translation
	* out - output packet
	* tcp - pointer to tcp header in packet
	* checksum - pseudo-header checksum
	* len - size of ip payload
	* returns: the highest position in the output clat_packet that's filled in
	*/
	int tcp_packet(clat_packet out, clat_packet_index pos, const struct tcphdr *tcp, uint32_t old_sum,
	uint32_t new_sum, size_t len) {
	const uint8_t *payload;
	size_t payload_size, header_size;

	if (len < sizeof(struct tcphdr)) {
	logmsg_dbg(ANDROID_LOG_ERROR, "tcp_packet/(too small)");
	return 0;
	}

	if (tcp->doff < 5) {
	logmsg_dbg(ANDROID_LOG_ERROR, "tcp_packet/tcp header length set to less than 5: %x", tcp->doff);
	return 0;
	}

	if ((size_t)tcp->doff * 4 > len) {
	logmsg_dbg(ANDROID_LOG_ERROR, "tcp_packet/tcp header length set too large: %x", tcp->doff);
	return 0;
	}

	header_size = tcp->doff * 4;
	payload = ((const uint8_t *)tcp) + header_size;
	payload_size = len - header_size;

	return tcp_translate(out, pos, tcp, header_size, old_sum, new_sum, payload, payload_size);
	}

	/* function: udp_translate
	* common between ipv4/ipv6 - setup checksum and send udp packet
	* out - output packet
	* udp - udp header
	* old_sum - pseudo-header checksum of old header
	* new_sum - pseudo-header checksum of new header
	* payload - tcp payload
	* payload_size - size of payload
	* returns: the highest position in the output clat_packet that's filled in
	*/
	int udp_translate(clat_packet out, clat_packet_index pos, const struct udphdr *udp,
	uint32_t old_sum, uint32_t new_sum, const uint8_t *payload, size_t payload_size) {
	struct udphdr *udp_targ = out[pos].iov_base;

	memcpy(udp_targ, udp, sizeof(struct udphdr));

	out[pos].iov_len = sizeof(struct udphdr);
	out[CLAT_POS_PAYLOAD].iov_base = (uint8_t *)payload;
	out[CLAT_POS_PAYLOAD].iov_len = payload_size;

	if (udp_targ->check) {
	udp_targ->check = ip_checksum_adjust(udp->check, old_sum, new_sum);
	} else {
	// Zero checksums are special. RFC 768 says, "An all zero transmitted checksum value means that
	// the transmitter generated no checksum (for debugging or for higher level protocols that
	// don't care)." However, in IPv6 zero UDP checksums were only permitted by RFC 6935 (2013). So
	// for safety we recompute it.
	udp_targ->check = 0; // Checksum field must be 0 when calculating checksum.
	udp_targ->check = packet_checksum(new_sum, out, pos);
	}

	// RFC 768: "If the computed checksum is zero, it is transmitted as all ones (the equivalent
	// in one's complement arithmetic)."
	if (!udp_targ->check) {
	udp_targ->check = 0xffff;
	}

	return CLAT_POS_PAYLOAD + 1;
	}

	/* function: tcp_translate
	* common between ipv4/ipv6 - setup checksum and send tcp packet
	* out - output packet
	* tcp - tcp header
	* header_size - size of tcp header including options
	* checksum - partial checksum covering ipv4/ipv6 header
	* payload - tcp payload
	* payload_size - size of payload
	* returns: the highest position in the output clat_packet that's filled in
	*/
	int tcp_translate(clat_packet out, clat_packet_index pos, const struct tcphdr *tcp,
	size_t header_size, uint32_t old_sum, uint32_t new_sum, const uint8_t *payload,
	size_t payload_size) {
	struct tcphdr *tcp_targ = out[pos].iov_base;
	out[pos].iov_len = header_size;

	if (header_size > MAX_TCP_HDR) {
	// A TCP header cannot be more than MAX_TCP_HDR bytes long because it's a 4-bit field that
	// counts in 4-byte words. So this can never happen unless there is a bug in the caller.
	logmsg(ANDROID_LOG_ERROR, "tcp_translate: header too long %d > %d, truncating", header_size,
	MAX_TCP_HDR);
	header_size = MAX_TCP_HDR;
	}

	memcpy(tcp_targ, tcp, header_size);

	out[CLAT_POS_PAYLOAD].iov_base = (uint8_t *)payload;
	out[CLAT_POS_PAYLOAD].iov_len = payload_size;

	tcp_targ->check = ip_checksum_adjust(tcp->check, old_sum, new_sum);

	return CLAT_POS_PAYLOAD + 1;
	}

	// Weak symbol so we can override it in the unit test.
	void send_rawv6(int fd, clat_packet out, int iov_len) __attribute__((weak));

	void send_rawv6(int fd, clat_packet out, int iov_len) {
	// A send on a raw socket requires a destination address to be specified even if the socket's
	// protocol is IPPROTO_RAW. This is the address that will be used in routing lookups; the
	// destination address in the packet header only affects what appears on the wire, not where the
	// packet is sent to.
	static struct sockaddr_in6 sin6 = { AF_INET6, 0, 0, { { { 0, 0, 0, 0 } } }, 0 };
	static struct msghdr msg = {
	.msg_name = &sin6,
	.msg_namelen = sizeof(sin6),
	};

	msg.msg_iov = out, msg.msg_iovlen = iov_len,
	sin6.sin6_addr = ((struct ip6_hdr *)out[CLAT_POS_IPHDR].iov_base)->ip6_dst;
	sendmsg(fd, &msg, 0);
	}

	/* function: translate_packet
	* takes a packet, translates it, and writes it to fd
	* fd - fd to write translated packet to
	* to_ipv6 - true if translating to ipv6, false if translating to ipv4
	* packet - packet
	* packetsize - size of packet
	*/
	void translate_packet(int fd, int to_ipv6, const uint8_t *packet, size_t packetsize) {
	int iov_len = 0;

	// Allocate buffers for all packet headers.
	struct tun_pi tun_targ;
	char iphdr[sizeof(struct ip6_hdr)];
	char fraghdr[sizeof(struct ip6_frag)];
	char transporthdr[MAX_TCP_HDR];
	char icmp_iphdr[sizeof(struct ip6_hdr)];
	char icmp_fraghdr[sizeof(struct ip6_frag)];
	char icmp_transporthdr[MAX_TCP_HDR];

	// iovec of the packets we'll send. This gets passed down to the translation functions.
	clat_packet out = {
	{ &tun_targ, 0 }, // Tunnel header.
	{ iphdr, 0 }, // IP header.
	{ fraghdr, 0 }, // Fragment header.
	{ transporthdr, 0 }, // Transport layer header.
	{ icmp_iphdr, 0 }, // ICMP error inner IP header.
	{ icmp_fraghdr, 0 }, // ICMP error fragmentation header.
	{ icmp_transporthdr, 0 }, // ICMP error transport layer header.
	{ NULL, 0 }, // Payload. No buffer, it's a pointer to the original payload.
	};

	if (to_ipv6) {
	iov_len = ipv4_packet(out, CLAT_POS_IPHDR, packet, packetsize);
	if (iov_len > 0) {
	send_rawv6(fd, out, iov_len);
	}
	} else {
	iov_len = ipv6_packet(out, CLAT_POS_IPHDR, packet, packetsize);
	if (iov_len > 0) {
	fill_tun_header(&tun_targ, ETH_P_IP);
	out[CLAT_POS_TUNHDR].iov_len = sizeof(tun_targ);
	send_tun(fd, out, iov_len);
	}
	}
	}