From 0d47952611198ef6b1163f366dc03922d20b1475 Mon Sep 17 00:00:00 2001 From: Daniel Baumann Date: Wed, 17 Apr 2024 09:42:04 +0200 Subject: Adding upstream version 7.94+git20230807.3be01efb1+dfsg. Signed-off-by: Daniel Baumann --- libnetutil/ICMPv6Header.cc | 1358 ++++++++++++++++++++++++++++++++++++++++++++ 1 file changed, 1358 insertions(+) create mode 100644 libnetutil/ICMPv6Header.cc (limited to 'libnetutil/ICMPv6Header.cc') diff --git a/libnetutil/ICMPv6Header.cc b/libnetutil/ICMPv6Header.cc new file mode 100644 index 0000000..ee28151 --- /dev/null +++ b/libnetutil/ICMPv6Header.cc @@ -0,0 +1,1358 @@ +/*************************************************************************** + * ICMPv6Header.cc -- The ICMPv6Header Class represents an ICMP version 6 * + * packet. It contains methods to set any header field. In general, these * + * methods do error checkings and byte order conversion. * + * * + ***********************IMPORTANT NMAP LICENSE TERMS************************ + * + * The Nmap Security Scanner is (C) 1996-2023 Nmap Software LLC ("The Nmap + * Project"). Nmap is also a registered trademark of the Nmap Project. + * + * This program is distributed under the terms of the Nmap Public Source + * License (NPSL). The exact license text applying to a particular Nmap + * release or source code control revision is contained in the LICENSE + * file distributed with that version of Nmap or source code control + * revision. More Nmap copyright/legal information is available from + * https://nmap.org/book/man-legal.html, and further information on the + * NPSL license itself can be found at https://nmap.org/npsl/ . This + * header summarizes some key points from the Nmap license, but is no + * substitute for the actual license text. + * + * Nmap is generally free for end users to download and use themselves, + * including commercial use. It is available from https://nmap.org. + * + * The Nmap license generally prohibits companies from using and + * redistributing Nmap in commercial products, but we sell a special Nmap + * OEM Edition with a more permissive license and special features for + * this purpose. See https://nmap.org/oem/ + * + * If you have received a written Nmap license agreement or contract + * stating terms other than these (such as an Nmap OEM license), you may + * choose to use and redistribute Nmap under those terms instead. + * + * The official Nmap Windows builds include the Npcap software + * (https://npcap.com) for packet capture and transmission. It is under + * separate license terms which forbid redistribution without special + * permission. So the official Nmap Windows builds may not be redistributed + * without special permission (such as an Nmap OEM license). + * + * Source is provided to this software because we believe users have a + * right to know exactly what a program is going to do before they run it. + * This also allows you to audit the software for security holes. + * + * Source code also allows you to port Nmap to new platforms, fix bugs, and add + * new features. You are highly encouraged to submit your changes as a Github PR + * or by email to the dev@nmap.org mailing list for possible incorporation into + * the main distribution. Unless you specify otherwise, it is understood that + * you are offering us very broad rights to use your submissions as described in + * the Nmap Public Source License Contributor Agreement. This is important + * because we fund the project by selling licenses with various terms, and also + * because the inability to relicense code has caused devastating problems for + * other Free Software projects (such as KDE and NASM). + * + * The free version of Nmap 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. Warranties, + * indemnification and commercial support are all available through the + * Npcap OEM program--see https://nmap.org/oem/ + * + ***************************************************************************/ +/* This code was originally part of the Nping tool. */ + +#include "ICMPv6Header.h" +#include "IPv6Header.h" +#include + +/******************************************************************************/ +/* CONTRUCTORS, DESTRUCTORS AND INITIALIZATION METHODS */ +/******************************************************************************/ +ICMPv6Header::ICMPv6Header() { + this->reset(); +} /* End of ICMPv6Header constructor */ + + +ICMPv6Header::~ICMPv6Header() { + +} /* End of ICMPv6Header destructor */ + + +/** Sets every attribute to its default value */ +void ICMPv6Header::reset(){ + memset(&this->h, 0, sizeof(nping_icmpv6_hdr_t)); + h_du = (dest_unreach_msg_t *)this->h.data; + h_ptb= (pkt_too_big_msg_t *)this->h.data; + h_te = (time_exceeded_msg_t *)this->h.data; + h_pp = (parameter_problem_msg_t *)this->h.data; + h_e = (echo_msg_t *)this->h.data; + h_ra = (router_advert_msg_t *)this->h.data; + h_rs = (router_solicit_msg_t *)this->h.data; + h_na = (neighbor_advert_msg_t *)this->h.data; + h_ns = (neighbor_solicit_msg_t *)this->h.data; + h_r = (redirect_msg_t *)this->h.data; + h_rr = (router_renumbering_msg_t *)this->h.data; + h_ni = (nodeinfo_msg_t *)this->h.data; + h_mld= (mld_msg_t *)this->h.data; +} /* End of reset() */ + + +/******************************************************************************/ +/* PacketElement:: OVERWRITTEN METHODS */ +/******************************************************************************/ + +/** @warning This method is essential for the superclass getBinaryBuffer() + * method to work. Do NOT change a thing unless you know what you're doing */ +u8 *ICMPv6Header::getBufferPointer(){ + return (u8*)(&this->h); +} /* End of getBufferPointer() */ + + +/** Stores supplied packet in the internal buffer so the information + * can be accessed using the standard get & set methods. + * @warning The ICMPv6Header class is able to hold a maximum of + * sizeof(nping_icmpv6_hdr_t) bytes. If the supplied buffer is longer than + * that, only the first 1508 bytes will be stored in the internal buffer. + * @warning Supplied len MUST be at least 8 bytes (min ICMPv6 header length). + * @return OP_SUCCESS on success and OP_FAILURE in case of error */ +int ICMPv6Header::storeRecvData(const u8 *buf, size_t len){ + if(buf==NULL || lenlength=0; + return OP_FAILURE; + }else{ + int stored_len = MIN( sizeof(nping_icmpv6_hdr_t), len); + this->reset(); /* Re-init the object, just in case the caller had used it already */ + this->length=stored_len; + memcpy(&(this->h), buf, stored_len); + } + return OP_SUCCESS; +} /* End of storeRecvData() */ + + +/* Returns a protocol identifier. This is used by packet parsing funtions + * that return linked lists of PacketElement objects, to determine the protocol + * the object represents. */ +int ICMPv6Header::protocol_id() const { + return HEADER_TYPE_ICMPv6; +} /* End of protocol_id() */ + + +/** Determines if the data stored in the object after an storeRecvData() call + * is valid and safe to use. This mainly checks the length of the data but may + * also test the value of certain protocol fields to ensure their correctness. + * @return the length, in bytes, of the header, if its found to be valid or + * OP_FAILURE (-1) otherwise. */ +int ICMPv6Header::validate(){ + int should_have=this->getHeaderLengthFromType( this->getType() ); + if(this->length < should_have){ + return OP_FAILURE; + }else{ + /* WARNING: If we extend this class to support new ICMPv6 types with + * a variable length header (not even sure they exist), we need to + * parse the objects data and return our actual size, not this size that + * is obtained from the type. */ + return should_have; + } +} /* End of validate() */ + + +/** Prints the contents of the header and calls print() on the next protocol + * header in the chain (if there is any). + * @return OP_SUCCESS on success and OP_FAILURE in case of error. */ +int ICMPv6Header::print(FILE *output, int detail) const { + u8 type=this->getType(); + u8 code=this->getCode(); + const char *typestr=this->type2string(type, code); + + fprintf(output, "ICMPv6[%s", typestr); + if(detail>=PRINT_DETAIL_MED) + fprintf(output, " (type=%u/code=%u)", type, code); + + switch(type) { + + case ICMPv6_UNREACH: + case ICMPv6_TIMXCEED: + if(detail>=PRINT_DETAIL_HIGH) + fprintf(output, " unused=%lu", (long unsigned int)this->getUnused()); + break; + + case ICMPv6_ROUTERSOLICIT: + if(detail>=PRINT_DETAIL_HIGH) + fprintf(output, " reserved=%lu", (long unsigned int)this->getReserved()); + break; + + case ICMPv6_PKTTOOBIG: + fprintf(output, " mtu=%lu", (long unsigned int)this->getMTU()); + break; + + case ICMPv6_PARAMPROB: + fprintf(output, " pointer=%lu", (long unsigned int)this->getPointer()); + break; + + case ICMPv6_ECHO: + case ICMPv6_ECHOREPLY: + fprintf(output, " id=%u seq=%u", this->getIdentifier(), this->getSequence()); + break; + + case ICMPv6_NODEINFOQUERY: + case ICMPv6_NODEINFORESP: + if(this->getNodeInfoFlags()!=0){ + fprintf(output, " flags="); + if(this->getNodeInfoFlags() & ICMPv6_NI_FLAG_T) + fprintf(output, "T"); + if(this->getNodeInfoFlags() & ICMPv6_NI_FLAG_A) + fprintf(output, "A"); + if(this->getNodeInfoFlags() & ICMPv6_NI_FLAG_C) + fprintf(output, "C"); + if(this->getNodeInfoFlags() & ICMPv6_NI_FLAG_L) + fprintf(output, "L"); + if(this->getNodeInfoFlags() & ICMPv6_NI_FLAG_G) + fprintf(output, "G"); + if(this->getNodeInfoFlags() & ICMPv6_NI_FLAG_S) + fprintf(output, "S"); + } + if(detail>=PRINT_DETAIL_HIGH){ + #ifdef WIN32 + fprintf(output, " nonce=%I64u", (long long unsigned int)this->getNonce()); + #else + fprintf(output, " nonce=%llu", (long long unsigned int)this->getNonce()); + #endif + } + break; + + default: + /* Print nothing */ + break; + } + + if(detail>=PRINT_DETAIL_HIGH) + fprintf(output, " csum=0x%04X", ntohs(this->getSum())); + fprintf(output, "]"); + if(this->next!=NULL){ + print_separator(output, detail); + next->print(output, detail); + } + return OP_SUCCESS; +} /* End of print() */ + + +/******************************************************************************/ +/* PROTOCOL-SPECIFIC METHODS */ +/******************************************************************************/ + +/******************************************************************************/ +/* ICMPv6 COMMON HEADER */ +/******************************************************************************/ + +/** Set ICMPv6 type field */ +int ICMPv6Header::setType(u8 val){ + this->h.type = val; + this->length = getHeaderLengthFromType(val); + return OP_SUCCESS; +} /* End of setType() */ + + +/** Returns ICMPv6 type field */ +u8 ICMPv6Header::getType() const { + return this->h.type; +} /* End of getType() */ + + +/* Returns true if the supplied ICMPv6 type is supported by this class */ +bool ICMPv6Header::validateType(u8 val){ + switch( val ){ + case ICMPv6_UNREACH: + case ICMPv6_PKTTOOBIG: + case ICMPv6_TIMXCEED: + case ICMPv6_PARAMPROB: + case ICMPv6_ECHO: + case ICMPv6_ECHOREPLY: + case ICMPv6_ROUTERSOLICIT: + case ICMPv6_ROUTERADVERT: + case ICMPv6_NGHBRSOLICIT: + case ICMPv6_NGHBRADVERT: + case ICMPv6_REDIRECT: + case ICMPv6_RTRRENUM: + return true; + break; + + default: + return false; + break; + } + return false; +} /* End of validateType() */ + + +bool ICMPv6Header::validateType(){ + return validateType(this->h.type); +} /* End of validateType() */ + + +/** Set ICMPv6 code field */ +int ICMPv6Header::setCode(u8 val){ + this->h.code = val; + return OP_SUCCESS; +} /* End of setCode() */ + + +/** Returns ICMPv6 code field */ +u8 ICMPv6Header::getCode() const { + return this->h.code; +} /* End of getCode() */ + + +/** Given an ICMP Type and a code, determines whether the code corresponds to + * a RFC compliant code (eg: code 0x03 for "port unreachable" in ICMP + * Unreachable messages) or just some other bogus code. */ +bool ICMPv6Header::validateCode(u8 type, u8 code){ +// switch (type){ +// +// case ICMPv6_UNREACH: +// return (code==0); +// break; +// +// case ICMPv6_PKTTOOBIG: +// switch( code ){ +// case XXXXXXXXXXXX: +// case YYYYYYYYYYYY: +// case ZZZZZZZZZZZZ: +// return true; +// break; +// } +// break; +// +// case ICMPv6_TIMXCEED: +// +// break; +// +// case ICMPv6_PARAMPROB: +// +// break; +// +// case ICMPv6_ECHO: +// +// break; +// +// case ICMPv6_ECHOREPLY: +// +// break; +// +// case ICMPv6_ROUTERSOLICIT: +// case ICMPv6_ROUTERADVERT: +// case ICMPv6_NGHBRSOLICIT: +// case ICMPv6_NGHBRADVERT: +// case ICMPv6_REDIRECT: +// break; +// +// default: +// return false; +// break; +// } + return false; +} /* End of validateCode() */ + + +/** Computes the ICMP header checksum and sets the checksum field to the right + * value. + * @warning This method requires the ICMPv6Object to be linked to an IPv6Header + * object, so make sure setNextElement() has been called like this: + * + * IPv6Header ip6; + * ICMPv6Header icmp6; + * [...] # Set header fields + * ip6.setNextElement(&icmp6); + * icmp6.setSum(); + * + * Note that there can be a number of extension headers between the ICMPv6 + * header and the IPv6 one, but all of them need to be linked in order for this + * method to traverse the list of headers and find the IPv6 source and + * destination address, required to compute the checksum. So things like the + * following are OK: + * + * IPv6Header ip6; + * HopByHopHeader hop; + * RoutingHeader rte; + * FragmentHeader frg; + * ICMPv6Header icmp6; + * [...] # Set whatever header fields you need + * ip6.setNextElement(&hop); + * hop.setNextElement(&rte); + * rte.setNextElement(&frg); + * frg.setNextElement(&icmp6); + * icmp6.setSum(); # setSum() will be able to reach the IPv6Header. + * + */ +int ICMPv6Header::setSum(){ + PacketElement *hdr; + hdr=this->getPrevElement(); + /* Traverse the list of headers backwards until we find the IPv6 header */ + while(hdr!=NULL){ + if (hdr->protocol_id()==HEADER_TYPE_IPv6){ + IPv6Header *v6hdr=(IPv6Header *)hdr; + struct in6_addr i6src, i6dst; + this->h.checksum=0; + memcpy(i6src.s6_addr, v6hdr->getSourceAddress(), 16); + memcpy(i6dst.s6_addr, v6hdr->getDestinationAddress(), 16); + u8 *buff=(u8 *)safe_malloc(this->getLen()); + this->dumpToBinaryBuffer(buff, this->getLen()); + this->h.checksum=ipv6_pseudoheader_cksum(&i6src, &i6dst, this->protocol_id(), this->getLen(), buff); + free(buff); + return OP_SUCCESS; + }else{ + hdr=hdr->getPrevElement(); + } + } + return OP_FAILURE; +} /* End of setSum() */ + + +/** @warning Sum is set to supplied value with NO byte ordering conversion + * performed. + * @warning If sum is supplied this way, no error checks are made. Caller is + * responsible for the correctness of the value. */ +int ICMPv6Header::setSum(u16 s){ + this->h.checksum=s; + return OP_SUCCESS; +} /* End of setSum() */ + + +/** Returns the value of the checksum field. + * @warning The returned value is in NETWORK byte order, no conversion is + * performed */ +u16 ICMPv6Header::getSum() const{ + return this->h.checksum; +} /* End of getSum() */ + + +/** @warning Supplied value MUST be in host byte order because it will get + * converted by this method using htonl() */ +int ICMPv6Header::setReserved(u32 val){ + u32 aux32=0; + u8 *auxpnt=(u8 *)&aux32; + + switch(this->h.type){ + + case ICMPv6_UNREACH: + this->h_du->unused=htonl(val); + break; + + case ICMPv6_TIMXCEED: + this->h_te->unused=htonl(val); + break; + + case ICMPv6_ROUTERSOLICIT: + this->h_rs->reserved=htonl(val); + break; + + case ICMPv6_NGHBRSOLICIT: + this->h_ns->reserved=htonl(val); + break; + + case ICMPv6_REDIRECT: + this->h_r->reserved=htonl(val); + break; + + + case ICMPv6_NGHBRADVERT: + /* The reserved field in Neighbor Advertisement messages is only + * 24-bits long so we convert the supplied value to big endian and + * use only the 24 least significant bits. */ + aux32=htonl(val); + this->h_na->reserved[0]=auxpnt[1]; + this->h_na->reserved[1]=auxpnt[2]; + this->h_na->reserved[2]=auxpnt[3]; + break; + + case ICMPv6_RTRRENUM: + this->h_rr->reserved=htonl(val); + break; + + /* Types that don't have a reserved field */ + case ICMPv6_ROUTERADVERT: + case ICMPv6_ECHO: + case ICMPv6_ECHOREPLY: + case ICMPv6_PARAMPROB: + case ICMPv6_PKTTOOBIG: + default: + return OP_FAILURE; + break; + } + return OP_SUCCESS; +} /* End of setReserved() */ + + +/** @warning Returned value is in host byte order */ +u32 ICMPv6Header::getReserved() const { + u32 aux32=0; + u8 *auxpnt=(u8 *)&aux32; + + switch(this->h.type){ + + case ICMPv6_UNREACH: + return ntohl(this->h_du->unused); + break; + + case ICMPv6_TIMXCEED: + return ntohl(this->h_te->unused); + break; + + case ICMPv6_ROUTERSOLICIT: + return ntohl(this->h_rs->reserved); + break; + + case ICMPv6_NGHBRSOLICIT: + return ntohl(this->h_ns->reserved); + break; + + case ICMPv6_REDIRECT: + return ntohl(this->h_r->reserved); + break; + + case ICMPv6_NGHBRADVERT: + /* The reserved field in Neighbor Advertisement messages is only + * 24-bits long so we extract the stored value and convert it to host + * byte order. */ + auxpnt[0]=0; + auxpnt[1]=this->h_na->reserved[0]; + auxpnt[2]=this->h_na->reserved[1]; + auxpnt[3]=this->h_na->reserved[2]; + return ntohl(aux32); + break; + + case ICMPv6_RTRRENUM: + return ntohl(this->h_rr->reserved); + break; + + /* Types that don't have a reserved field */ + case ICMPv6_ROUTERADVERT: + case ICMPv6_ECHO: + case ICMPv6_ECHOREPLY: + case ICMPv6_PARAMPROB: + case ICMPv6_PKTTOOBIG: + default: + return 0; + break; + } +} /* End of setReserved() */ + +int ICMPv6Header::setUnused(u32 val){ + return this->setReserved(val); +} /* End of setUnused() */ + + +u32 ICMPv6Header::getUnused() const { + return this->getReserved(); +} /* End of getUnused() */ + + +int ICMPv6Header::setFlags(u8 val){ + switch(this->h.type){ + + case ICMPv6_ROUTERADVERT: + this->h_ra->autoconfig_flags=val; + break; + + case ICMPv6_NGHBRADVERT: + this->h_na->flags=val; + break; + + case ICMPv6_RTRRENUM: + this->h_rr->flags=val; + break; + + case ICMPv6_NODEINFOQUERY: + case ICMPv6_NODEINFORESP: + netutil_fatal("setFlags() cannot be used in NI, use setNodeInfoFlags() instead\n"); + break; + + /* Types that don't have a flags field */ + case ICMPv6_TIMXCEED: + case ICMPv6_UNREACH: + case ICMPv6_ROUTERSOLICIT: + case ICMPv6_NGHBRSOLICIT: + case ICMPv6_REDIRECT: + case ICMPv6_ECHO: + case ICMPv6_ECHOREPLY: + case ICMPv6_PARAMPROB: + case ICMPv6_PKTTOOBIG: + default: + return OP_FAILURE; + break; + } + return OP_SUCCESS; +} /* End of setFlags() */ + + +u8 ICMPv6Header::getFlags() const { + switch(this->h.type){ + + case ICMPv6_ROUTERADVERT: + return this->h_ra->autoconfig_flags; + break; + + case ICMPv6_NGHBRADVERT: + return this->h_na->flags; + break; + + case ICMPv6_RTRRENUM: + return this->h_rr->flags; + break; + + case ICMPv6_NODEINFOQUERY: + case ICMPv6_NODEINFORESP: + netutil_fatal("getFlags() cannot be used in NI, use getNodeInfoFlags() instead\n"); + return 0; + break; + + /* Types that don't have a flags field */ + case ICMPv6_TIMXCEED: + case ICMPv6_UNREACH: + case ICMPv6_ROUTERSOLICIT: + case ICMPv6_NGHBRSOLICIT: + case ICMPv6_REDIRECT: + case ICMPv6_ECHO: + case ICMPv6_ECHOREPLY: + case ICMPv6_PARAMPROB: + case ICMPv6_PKTTOOBIG: + default: + return 0; + break; + } +} /* End of getFlags() */ + +/******************************************************************************/ +/* ICMPv6 DESTINATION UNREACHABLE */ +/******************************************************************************/ + +/******************************************************************************/ +/* ICMPv6 PACKET TOO BIG */ +/******************************************************************************/ +int ICMPv6Header::setMTU(u32 mtu){ + this->h_ptb->mtu=htonl(mtu); + return OP_SUCCESS; +} /* End of setMTU() */ + +u32 ICMPv6Header::getMTU() const { + return ntohl(this->h_ptb->mtu); +} /* End of getMTU() */ + +/******************************************************************************/ +/* ICMPv6 TIME EXCEEDED */ +/******************************************************************************/ + +/******************************************************************************/ +/* ICMPv6 PARAMETER PROBLEM */ +/******************************************************************************/ +int ICMPv6Header::setPointer(u32 pnt){ + this->h_pp->pointer=htonl(pnt); + return OP_SUCCESS; +} /* End of setPointer() */ + + +u32 ICMPv6Header::getPointer() const { + return ntohl(this->h_pp->pointer); +} /* End of getPointer() */ + +/******************************************************************************/ +/* ICMPv6 ECHO */ +/******************************************************************************/ +int ICMPv6Header::setIdentifier(u16 val){ + this->h_e->id=htons(val); + return OP_SUCCESS; +} /* End of setIdentifier() */ + + +u16 ICMPv6Header::getIdentifier() const{ + return ntohs(this->h_e->id); +} /* End of getIdentifier() */ + + +int ICMPv6Header::setSequence(u16 val){ + switch(this->h.type){ + case ICMPv6_RTRRENUM: + this->h_rr->seq=htonl( ((u32)val) ); + break; + + case ICMPv6_ECHO: + case ICMPv6_ECHOREPLY: + this->h_e->seq=htons(val); + break; + + default: + return OP_FAILURE; + break; + } + return OP_SUCCESS; +} /* End of setSequence() */ + + +int ICMPv6Header::setSequence(u32 val){ + switch(this->h.type){ + case ICMPv6_RTRRENUM: + this->h_rr->seq=htonl(val); + break; + + case ICMPv6_ECHO: + case ICMPv6_ECHOREPLY: + this->h_e->seq=htons( ((u16)val) ); + break; + + default: + return OP_FAILURE; + break; + } + return OP_SUCCESS; +} /* End of setSequence() */ + + +u32 ICMPv6Header::getSequence() const{ + switch(this->h.type){ + case ICMPv6_RTRRENUM: + return ntohl(this->h_rr->seq); + break; + + case ICMPv6_ECHO: + case ICMPv6_ECHOREPLY: + return (u32)ntohs(this->h_e->seq); + break; + } + return 0; +} /* End of getSequence() */ + + +/******************************************************************************/ +/* ICMPv6 ROUTER ADVERTISEMENT */ +/******************************************************************************/ +int ICMPv6Header::setCurrentHopLimit(u8 val){ + this->h_ra->current_hop_limit=val; + return OP_SUCCESS; +} /* End of setCurrentHopLimit() */ + +u8 ICMPv6Header::getCurrentHopLimit() const { + return this->h_ra->current_hop_limit; +} /* End of getCurrentHopLimit() */ + +int ICMPv6Header::setRouterLifetime(u16 val){ + this->h_ra->router_lifetime=val; + return OP_SUCCESS; +} /* End of setRouterLifetime() */ + +u16 ICMPv6Header::getRouterLifetime() const { + return this->h_ra->router_lifetime; +} /* End of getRouterLifetime() */ + +int ICMPv6Header::setReachableTime(u32 val){ + this->h_ra->reachable_time=val; + return OP_SUCCESS; +} /* End of setReachableTime() */ + +u32 ICMPv6Header::getReachableTime() const { + return this->h_ra->reachable_time; +} /* End of getReachableTime() */ + +int ICMPv6Header::setRetransmissionTimer(u32 val){ + this->h_ra->retransmission_timer=val; + return OP_SUCCESS; +} /* End of setRetransmissionTimer() */ + +u32 ICMPv6Header::getRetransmissionTimer() const { + return this->h_ra->retransmission_timer; +} /* End of getRetransmissionTimer() */ + +/******************************************************************************/ +/* ICMPv6 ROUTER SOLICITATION */ +/******************************************************************************/ + +/******************************************************************************/ +/* ICMPv6 NEIGHBOR ADVERTISEMENT */ +/******************************************************************************/ + +int ICMPv6Header::setTargetAddress(struct in6_addr addr){ + switch(this->h.type){ + case ICMPv6_NGHBRADVERT: + memcpy(this->h_na->target_address, addr.s6_addr, 16); + break; + + case ICMPv6_NGHBRSOLICIT: + memcpy(this->h_ns->target_address, addr.s6_addr, 16); + break; + + case ICMPv6_REDIRECT: + memcpy(this->h_r->target_address, addr.s6_addr, 16); + break; + + default: + return OP_FAILURE; + break; + } + return OP_SUCCESS; +} /* End of setTargetAddress() */ + + +struct in6_addr ICMPv6Header::getTargetAddress() const { + struct in6_addr addr; + memset(&addr, 0, sizeof(struct in6_addr)); + + switch(this->h.type){ + case ICMPv6_NGHBRADVERT: + memcpy(addr.s6_addr, this->h_na->target_address, 16); + break; + + case ICMPv6_NGHBRSOLICIT: + memcpy(addr.s6_addr, this->h_ns->target_address, 16); + break; + + case ICMPv6_REDIRECT: + memcpy(addr.s6_addr, this->h_r->target_address, 16); + break; + } + return addr; +} /* End of setTargetAddress() */ + + +int ICMPv6Header::setDestinationAddress(struct in6_addr addr){ + switch(this->h.type){ + case ICMPv6_REDIRECT: + memcpy(this->h_r->destination_address, addr.s6_addr, 16); + break; + + default: + return OP_FAILURE; + break; + } + return OP_SUCCESS; +} /* End of setDestinationAddress() */ + + +struct in6_addr ICMPv6Header::getDestinationAddress() const { + struct in6_addr addr; + memset(&addr, 0, sizeof(struct in6_addr)); + + switch(this->h.type){ + case ICMPv6_REDIRECT: + memcpy(addr.s6_addr, this->h_r->destination_address, 16); + break; + } + return addr; +} /* End of setTargetAddress() */ + + +/******************************************************************************/ +/* ICMPv6 NEIGHBOR SOLICITATION */ +/******************************************************************************/ + +/******************************************************************************/ +/* ICMPv6 REDIRECT */ +/******************************************************************************/ + +/******************************************************************************/ +/* ICMPv6 ROUTER RENUMBERING */ +/******************************************************************************/ +int ICMPv6Header::setSegmentNumber(u8 val){ + this->h_rr->segment_number=val; + return OP_SUCCESS; +} /* End of setSegmentNumber() */ + +u8 ICMPv6Header::getSegmentNumber() const { + return this->h_rr->segment_number; +} /* End of getSegmentNumber() */ + +int ICMPv6Header::setMaxDelay(u16 val){ + switch(this->h.type){ + case ICMPv6_RTRRENUM: + this->h_rr->max_delay=htons(val); + return OP_SUCCESS; + break; + + case ICMPv6_GRPMEMBQUERY: + case ICMPv6_GRPMEMBREP: + case ICMPv6_GRPMEMBRED: + this->h_mld->max_response_delay=htons(val); + return OP_SUCCESS; + break; + + default: + return OP_FAILURE; + break; + } +} /* End of setMaxDelay() */ + + +u16 ICMPv6Header::getMaxDelay() const { + switch(this->h.type){ + case ICMPv6_RTRRENUM: + return ntohs(this->h_rr->max_delay); + break; + + case ICMPv6_GRPMEMBQUERY: + case ICMPv6_GRPMEMBREP: + case ICMPv6_GRPMEMBRED: + return ntohs(this->h_mld->max_response_delay); + break; + + default: + return 0; + break; + } +} /* End of getMaxDelay() */ + + + +/******************************************************************************/ +/* ICMPv6 NODE INFORMATION QUERIES */ +/******************************************************************************/ +/** Set NI Qtype */ +int ICMPv6Header::setQtype(u16 val){ + this->h_ni->qtype = htons(val); + return OP_SUCCESS; +} /* End of setQtype() */ + + +/** Returns NI Qtype */ +u16 ICMPv6Header::getQtype() const { + return ntohs(this->h_ni->qtype); +} /* End of getQtype() */ + + +/** Set NI Flags */ +int ICMPv6Header::setNodeInfoFlags(u16 val){ + this->h_ni->flags = htons(val); + return OP_SUCCESS; +} /* End of setNodeInfoFlags() */ + + +/** Returns NI Flags */ +u16 ICMPv6Header::getNodeInfoFlags() const { + return ntohs(this->h_ni->flags); +} /* End of getNodeInfoFlags() */ + + +/* 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + | unused |G|S|L|C|A|T| + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ */ + +/* Set NI Flag G */ +int ICMPv6Header::setG(bool flag_value){ + u16 current_flags = this->getNodeInfoFlags(); + if(flag_value) + current_flags = current_flags | 0x0020; + else + current_flags = current_flags & ~0x0020; + this->setNodeInfoFlags(current_flags); + return OP_SUCCESS; +} /* End of setG() */ + + +/* Get NI Flag G */ +bool ICMPv6Header::getG() const { + return this->getNodeInfoFlags() & 0x0020; +} /* End of getG() */ + + +/* Set NI Flag S */ +int ICMPv6Header::setS(bool flag_value){ + u16 current_flags = this->getNodeInfoFlags(); + if(flag_value) + current_flags = current_flags | 0x0010; + else + current_flags = current_flags & ~0x0010; + this->setNodeInfoFlags(current_flags); + return OP_SUCCESS; +} /* End of setS() */ + + +/* Get NI Flag S */ +bool ICMPv6Header::getS() const { + return this->getNodeInfoFlags() & 0x0010; +} /* End of getS() */ + + +/* Set NI Flag L */ +int ICMPv6Header::setL(bool flag_value){ + u16 current_flags = this->getNodeInfoFlags(); + if(flag_value) + current_flags = current_flags | 0x0008; + else + current_flags = current_flags & ~0x0008; + this->setNodeInfoFlags(current_flags); + return OP_SUCCESS; +} /* End of setL() */ + + +/* Get NI Flag L */ +bool ICMPv6Header::getL() const { + return this->getNodeInfoFlags() & 0x0008; +} /* End of getL() */ + + +/* Set NI Flag C */ +int ICMPv6Header::setC(bool flag_value){ + u16 current_flags = this->getNodeInfoFlags(); + if(flag_value) + current_flags = current_flags | 0x0004; + else + current_flags = current_flags & ~0x0004; + this->setNodeInfoFlags(current_flags); + return OP_SUCCESS; +} /* End of setC() */ + + +/* Get NI Flag C */ +bool ICMPv6Header::getC() const { + return this->getNodeInfoFlags() & 0x0004; +} /* End of getC() */ + + +/* Set NI Flag A */ +int ICMPv6Header::setA(bool flag_value){ + u16 current_flags = this->getNodeInfoFlags(); + if(flag_value) + current_flags = current_flags | 0x0002; + else + current_flags = current_flags & ~0x0002; + this->setNodeInfoFlags(current_flags); + return OP_SUCCESS; +} /* End of setA() */ + + +/* Get NI Flag A */ +bool ICMPv6Header::getA() const { + return this->getNodeInfoFlags() & 0x0002; +} /* End of getA() */ + + +/* Set NI Flag T */ +int ICMPv6Header::setT(bool flag_value){ + u16 current_flags = this->getNodeInfoFlags(); + if(flag_value) + current_flags = current_flags | 0x0001; + else + current_flags = current_flags & ~0x0001; + this->setNodeInfoFlags(current_flags); + return OP_SUCCESS; +} /* End of setT() */ + + +/* Get NI Flag T */ +bool ICMPv6Header::getT() const { + return this->getNodeInfoFlags() & 0x0001; +} /* End of getT() */ + + +/* Set the Nonce field. */ +int ICMPv6Header::setNonce(u64 nonce_value){ + this->h_ni->nonce=nonce_value; + return OP_SUCCESS; +} /* End of setNonce() */ + + +/* Set the Nonce field. + * @warning: Supplied buffer must contain 8 bytes. */ +int ICMPv6Header::setNonce(const u8 *nonce){ + if(nonce==NULL) + return OP_FAILURE; + memcpy(&(this->h_ni->nonce), nonce, NI_NONCE_LEN); + return OP_SUCCESS; +} /* End of setNonce() */ + + +/* Returns a pointer to the nonce buffer. + * @warning: The returned pointer is guaranteed to point to an 8-byte buffer. + * However, what comes after the 8th byte is unspecified. */ +u64 ICMPv6Header::getNonce() const { + return this->h_ni->nonce; +} /* End of getNonce() */ + + +/******************************************************************************/ +/* MULTICAST LISTENER DISCOVERY */ +/******************************************************************************/ + +int ICMPv6Header::setMulticastAddress(struct in6_addr addr){ + switch(this->h.type){ + case ICMPv6_GRPMEMBQUERY: + case ICMPv6_GRPMEMBREP: + case ICMPv6_GRPMEMBRED: + memcpy(this->h_mld->mcast_address, addr.s6_addr, 16); + break; + + default: + return OP_FAILURE; + break; + } + + return OP_SUCCESS; +} /* End of setMulticastAddress() */ + + +struct in6_addr ICMPv6Header::getMulticastAddress() const { + struct in6_addr addr; + memset(&addr, 0, sizeof(struct in6_addr)); + + switch(this->h.type){ + case ICMPv6_GRPMEMBQUERY: + case ICMPv6_GRPMEMBREP: + case ICMPv6_GRPMEMBRED: + memcpy(addr.s6_addr, this->h_mld->mcast_address, 16); + break; + } + return addr; +} /* End of setMulticastAddress() */ + + +/******************************************************************************/ +/* MISCELLANEOUS STUFF */ +/******************************************************************************/ + +/** Returns the standard ICMPv6 header length for the supplied ICMP message type. + * @warning Return value corresponds strictly to the ICMP header, this is, + * the minimum length of the ICMP header, variable length payload is never + * included. For example, an ICMPv6 Redirect has a fixed header of 40 + * bytes but then the packet may contain ICMPv6 options. We only return 40 + * because we don't know in advance the total number of bytes for the message. + * Same applies to the rest of types. */ +int ICMPv6Header::getHeaderLengthFromType(u8 type) const { + + switch( type ){ + case ICMPv6_UNREACH: + return ICMPv6_UNREACH_LEN; + break; + case ICMPv6_PKTTOOBIG: + return ICMPv6_PKTTOOBIG_LEN; + break; + + case ICMPv6_TIMXCEED: + return ICMPv6_TIMXCEED_LEN; + break; + + case ICMPv6_PARAMPROB: + return ICMPv6_PARAMPROB_LEN; + break; + + case ICMPv6_ECHO: + return ICMPv6_ECHO_LEN; + break; + + case ICMPv6_ECHOREPLY: + return ICMPv6_ECHOREPLY_LEN; + break; + + case ICMPv6_ROUTERSOLICIT: + return ICMPv6_ROUTERSOLICIT_LEN; + break; + + case ICMPv6_ROUTERADVERT: + return ICMPv6_ROUTERADVERT_LEN; + break; + + case ICMPv6_NGHBRSOLICIT: + return ICMPv6_NGHBRSOLICIT_LEN; + break; + + case ICMPv6_NGHBRADVERT: + return ICMPv6_NGHBRADVERT_LEN; + break; + + case ICMPv6_REDIRECT: + return ICMPv6_REDIRECT_LEN; + break; + + case ICMPv6_RTRRENUM: + return ICMPv6_RTRRENUM_LEN; + break; + + case ICMPv6_NODEINFOQUERY: + case ICMPv6_NODEINFORESP: + return ICMPv6_NODEINFO_LEN; + break; + + case ICMPv6_GRPMEMBQUERY: + case ICMPv6_GRPMEMBREP: + case ICMPv6_GRPMEMBRED: + return ICMPv6_MLD_LEN; + break; + + /* Packets with non RFC-Compliant types will be represented as an 8-byte + * ICMPv6 header, just like the types that don't include additional info */ + default: + return ICMPv6_MIN_HEADER_LEN; + break; + } +} /* End of getHeaderLengthFromType() */ + + +/* Returns true if the packet is an ICMPv6 error message. */ +bool ICMPv6Header::isError() const { + switch( this->getType() ){ + case ICMPv6_UNREACH: + case ICMPv6_PKTTOOBIG: + case ICMPv6_TIMXCEED: + case ICMPv6_PARAMPROB: + return true; + break; + + default: + return false; + break; + } +} /* End of isError() */ + + +const char *ICMPv6Header::type2string(int type, int code) const { + switch(type) { + + case ICMPv6_UNREACH: + switch(code) { + case ICMPv6_UNREACH_NO_ROUTE: return "Network unreachable"; break; + case ICMPv6_UNREACH_PROHIBITED: return "Comm prohibited"; break; + case ICMPv6_UNREACH_BEYOND_SCOPE: return "Beyond scope"; break; + case ICMPv6_UNREACH_ADDR_UNREACH: return "Address unreachable"; break; + case ICMPv6_UNREACH_PORT_UNREACH: return "Port unreachable"; break; + case ICMPv6_UNREACH_SRC_ADDR_FAILED: return "Source address failed"; break; + case ICMPv6_UNREACH_REJECT_ROUTE: return "Reject route"; break; + default: return "Destination unreachable (unknown code)"; break; + } + break; + + case ICMPv6_PKTTOOBIG: + return "Packet too big"; + break; + + case ICMPv6_TIMXCEED: + switch(code){ + case ICMPv6_TIMXCEED_HOP_EXCEEDED: return "HopLimit=0 in transit"; break; + case ICMPv6_TIMXCEED_REASS_EXCEEDED: return "Reassembly time exceeded"; break; + default: return "Time exceeded (unknown code)"; break; + } + break; + + case ICMPv6_PARAMPROB: + switch(code){ + case ICMPv6_PARAMPROB_FIELD: return "Parameter problem (bad field)"; break; + case ICMPv6_PARAMPROB_NEXT_HDR: return "Parameter problem (next header unknown)"; break; + case ICMPv6_PARAMPROB_OPTION: return "Parameter problem (bad option)"; break; + default: return "Parameter problem (unknown code)"; break; + } + break; + + case ICMPv6_ECHO: + return "Echo request"; + break; + case ICMPv6_ECHOREPLY: + return "Echo reply"; + break; + case ICMPv6_GRPMEMBQUERY: + return "Group membership query"; + break; + case ICMPv6_GRPMEMBREP: + return "Group membership report"; + break; + case ICMPv6_GRPMEMBRED: + return "Group membership reduction"; + break; + case ICMPv6_ROUTERSOLICIT: + return "Router sol"; + break; + case ICMPv6_ROUTERADVERT: + return "Router advert"; + break; + case ICMPv6_NGHBRSOLICIT: + return "Neighbor sol"; + break; + case ICMPv6_NGHBRADVERT: + return "Neighbor advert"; + break; + case ICMPv6_REDIRECT: + return "Redirect"; + break; + case ICMPv6_RTRRENUM: + switch(code){ + case ICMPv6_RTRRENUM_COMMAND: return "Renumbering command"; break; + case ICMPv6_RTRRENUM_RESULT: return "Renumbering result"; break; + case ICMPv6_RTRRENUM_SEQ_RESET: return "Renumbering reset"; break; + default: return "Router Renumbering (unknown code)"; break; + } + break; + case ICMPv6_NODEINFOQUERY: + switch(code){ + case ICMPv6_NODEINFOQUERY_IPv6ADDR: return "Node info query (IPv6 addr)"; break; + case ICMPv6_NODEINFOQUERY_NAME: return "Node info query (name)"; break; + case ICMPv6_NODEINFOQUERY_IPv4ADDR: return "Node info query (IPv4 addr)"; break; + default: return "Node info query (unknown code)"; break; + } + break; + + case ICMPv6_NODEINFORESP: + switch(code){ + case ICMPv6_NODEINFORESP_SUCCESS: return "Node info reply (success)"; break; + case ICMPv6_NODEINFORESP_REFUSED: return "Node info reply (refused)"; break; + case ICMPv6_NODEINFORESP_UNKNOWN: return "Node info reply (qtype unknown)"; break; + default: return "Node info reply (unknown code)"; break; + } + break; + + case ICMPv6_INVNGHBRSOLICIT: + return "Inverse neighbor sol"; + break; + + case ICMPv6_INVNGHBRADVERT: + return "Inverse neighbor advert"; + break; + + case ICMPv6_MLDV2: + return "MLDv2 report"; + break; + + case ICMPv6_AGENTDISCOVREQ: + return "Home agent request"; + break; + + case ICMPv6_AGENTDISCOVREPLY: + return "Home agent reply"; + break; + + case ICMPv6_MOBPREFIXSOLICIT: + return "Prefix sol"; + break; + + case ICMPv6_MOBPREFIXADVERT: + return "Prefix advert"; + break; + + case ICMPv6_CERTPATHSOLICIT: + return "Cert path sol"; + break; + + case ICMPv6_CERTPATHADVERT: + return "Cert path advert"; + break; + + case ICMPv6_EXPMOBILITY: + return "Experimental mobility"; + break; + + case ICMPv6_MRDADVERT: + return "Multicast router advert"; + break; + + case ICMPv6_MRDSOLICIT: + return "Multicast router sol"; + break; + + case ICMPv6_MRDTERMINATE: + return "Multicast router term"; + break; + + case ICMPv6_FMIPV6: + return "FMIPv6"; + break; + + default: + return "Unknown ICMPv6 type"; + break; + } /* End of ICMP Type switch */ + return "Unknown ICMPv6 type"; +} /* End of type2string() */ + + + -- cgit v1.2.3