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      1 /* -*- Mode: C; tab-width: 4 -*-
      2  *
      3  * Copyright (c) 2002-2003 Apple Computer, Inc. All rights reserved.
      4  *
      5  * Licensed under the Apache License, Version 2.0 (the "License");
      6  * you may not use this file except in compliance with the License.
      7  * You may obtain a copy of the License at
      8  *
      9  *     http://www.apache.org/licenses/LICENSE-2.0
     10  *
     11  * Unless required by applicable law or agreed to in writing, software
     12  * distributed under the License is distributed on an "AS IS" BASIS,
     13  * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
     14  * See the License for the specific language governing permissions and
     15  * limitations under the License.
     16 
     17    NOTE:
     18    If you're building an application that uses DNS Service Discovery
     19    this is probably NOT the header file you're looking for.
     20    In most cases you will want to use /usr/include/dns_sd.h instead.
     21 
     22    This header file defines the lowest level raw interface to mDNSCore,
     23    which is appropriate *only* on tiny embedded systems where everything
     24    runs in a single address space and memory is extremely constrained.
     25    All the APIs here are malloc-free, which means that the caller is
     26    responsible for passing in a pointer to the relevant storage that
     27    will be used in the execution of that call, and (when called with
     28    correct parameters) all the calls are guaranteed to succeed. There
     29    is never a case where a call can suffer intermittent failures because
     30    the implementation calls malloc() and sometimes malloc() returns NULL
     31    because memory is so limited that no more is available.
     32    This is primarily for devices that need to have precisely known fixed
     33    memory requirements, with absolutely no uncertainty or run-time variation,
     34    but that certainty comes at a cost of more difficult programming.
     35 
     36    For applications running on general-purpose desktop operating systems
     37    (Mac OS, Linux, Solaris, Windows, etc.) the API you should use is
     38    /usr/include/dns_sd.h, which defines the API by which multiple
     39    independent client processes communicate their DNS Service Discovery
     40    requests to a single "mdnsd" daemon running in the background.
     41 
     42    Even on platforms that don't run multiple independent processes in
     43    multiple independent address spaces, you can still use the preferred
     44    dns_sd.h APIs by linking in "dnssd_clientshim.c", which implements
     45    the standard "dns_sd.h" API calls, allocates any required storage
     46    using malloc(), and then calls through to the low-level malloc-free
     47    mDNSCore routines defined here. This has the benefit that even though
     48    you're running on a small embedded system with a single address space,
     49    you can still use the exact same client C code as you'd use on a
     50    general-purpose desktop system.
     51 
     52  */
     53 
     54 #ifndef __mDNSClientAPI_h
     55 #define __mDNSClientAPI_h
     56 
     57 #if defined(EFI32) || defined(EFI64) || defined(EFIX64)
     58 // EFI doesn't have stdarg.h unless it's building with GCC.
     59 #include "Tiano.h"
     60 #if !defined(__GNUC__)
     61 #define va_list         VA_LIST
     62 #define va_start(a, b)  VA_START(a, b)
     63 #define va_end(a)       VA_END(a)
     64 #define va_arg(a, b)    VA_ARG(a, b)
     65 #endif
     66 #else
     67 #include <stdarg.h>		// stdarg.h is required for for va_list support for the mDNS_vsnprintf declaration
     68 #endif
     69 
     70 #include "mDNSDebug.h"
     71 #if APPLE_OSX_mDNSResponder
     72 #include <uuid/uuid.h>
     73 #endif
     74 
     75 #ifdef __cplusplus
     76 	extern "C" {
     77 #endif
     78 
     79 // ***************************************************************************
     80 // Function scope indicators
     81 
     82 // If you see "mDNSlocal" before a function name in a C file, it means the function is not callable outside this file
     83 #ifndef mDNSlocal
     84 #define mDNSlocal static
     85 #endif
     86 // If you see "mDNSexport" before a symbol in a C file, it means the symbol is exported for use by clients
     87 // For every "mDNSexport" in a C file, there needs to be a corresponding "extern" declaration in some header file
     88 // (When a C file #includes a header file, the "extern" declarations tell the compiler:
     89 // "This symbol exists -- but not necessarily in this C file.")
     90 #ifndef mDNSexport
     91 #define mDNSexport
     92 #endif
     93 
     94 // Explanation: These local/export markers are a little habit of mine for signaling the programmers' intentions.
     95 // When "mDNSlocal" is just a synonym for "static", and "mDNSexport" is a complete no-op, you could be
     96 // forgiven for asking what purpose they serve. The idea is that if you see "mDNSexport" in front of a
     97 // function definition it means the programmer intended it to be exported and callable from other files
     98 // in the project. If you see "mDNSlocal" in front of a function definition it means the programmer
     99 // intended it to be private to that file. If you see neither in front of a function definition it
    100 // means the programmer forgot (so you should work out which it is supposed to be, and fix it).
    101 // Using "mDNSlocal" instead of "static" makes it easier to do a textual searches for one or the other.
    102 // For example you can do a search for "static" to find if any functions declare any local variables as "static"
    103 // (generally a bad idea unless it's also "const", because static storage usually risks being non-thread-safe)
    104 // without the results being cluttered with hundreds of matches for functions declared static.
    105 // - Stuart Cheshire
    106 
    107 // ***************************************************************************
    108 // Structure packing macro
    109 
    110 // If we're not using GNUC, it's not fatal.
    111 // Most compilers naturally pack the on-the-wire structures correctly anyway, so a plain "struct" is usually fine.
    112 // In the event that structures are not packed correctly, mDNS_Init() will detect this and report an error, so the
    113 // developer will know what's wrong, and can investigate what needs to be done on that compiler to provide proper packing.
    114 #ifndef packedstruct
    115  #if ((__GNUC__ > 2) || ((__GNUC__ == 2) && (__GNUC_MINOR__ >= 9)))
    116   #define packedstruct struct __attribute__((__packed__))
    117   #define packedunion  union  __attribute__((__packed__))
    118  #else
    119   #define packedstruct struct
    120   #define packedunion  union
    121  #endif
    122 #endif
    123 
    124 // ***************************************************************************
    125 #if 0
    126 #pragma mark - DNS Resource Record class and type constants
    127 #endif
    128 
    129 typedef enum							// From RFC 1035
    130 	{
    131 	kDNSClass_IN               = 1,		// Internet
    132 	kDNSClass_CS               = 2,		// CSNET
    133 	kDNSClass_CH               = 3,		// CHAOS
    134 	kDNSClass_HS               = 4,		// Hesiod
    135 	kDNSClass_NONE             = 254,	// Used in DNS UPDATE [RFC 2136]
    136 
    137 	kDNSClass_Mask             = 0x7FFF,// Multicast DNS uses the bottom 15 bits to identify the record class...
    138 	kDNSClass_UniqueRRSet      = 0x8000,// ... and the top bit indicates that all other cached records are now invalid
    139 
    140 	kDNSQClass_ANY             = 255,	// Not a DNS class, but a DNS query class, meaning "all classes"
    141 	kDNSQClass_UnicastResponse = 0x8000	// Top bit set in a question means "unicast response acceptable"
    142 	} DNS_ClassValues;
    143 
    144 typedef enum				// From RFC 1035
    145 	{
    146 	kDNSType_A = 1,			//  1 Address
    147 	kDNSType_NS,			//  2 Name Server
    148 	kDNSType_MD,			//  3 Mail Destination
    149 	kDNSType_MF,			//  4 Mail Forwarder
    150 	kDNSType_CNAME,			//  5 Canonical Name
    151 	kDNSType_SOA,			//  6 Start of Authority
    152 	kDNSType_MB,			//  7 Mailbox
    153 	kDNSType_MG,			//  8 Mail Group
    154 	kDNSType_MR,			//  9 Mail Rename
    155 	kDNSType_NULL,			// 10 NULL RR
    156 	kDNSType_WKS,			// 11 Well-known-service
    157 	kDNSType_PTR,			// 12 Domain name pointer
    158 	kDNSType_HINFO,			// 13 Host information
    159 	kDNSType_MINFO,			// 14 Mailbox information
    160 	kDNSType_MX,			// 15 Mail Exchanger
    161 	kDNSType_TXT,			// 16 Arbitrary text string
    162 	kDNSType_RP,			// 17 Responsible person
    163 	kDNSType_AFSDB,			// 18 AFS cell database
    164 	kDNSType_X25,			// 19 X_25 calling address
    165 	kDNSType_ISDN,			// 20 ISDN calling address
    166 	kDNSType_RT,			// 21 Router
    167 	kDNSType_NSAP,			// 22 NSAP address
    168 	kDNSType_NSAP_PTR,		// 23 Reverse NSAP lookup (deprecated)
    169 	kDNSType_SIG,			// 24 Security signature
    170 	kDNSType_KEY,			// 25 Security key
    171 	kDNSType_PX,			// 26 X.400 mail mapping
    172 	kDNSType_GPOS,			// 27 Geographical position (withdrawn)
    173 	kDNSType_AAAA,			// 28 IPv6 Address
    174 	kDNSType_LOC,			// 29 Location Information
    175 	kDNSType_NXT,			// 30 Next domain (security)
    176 	kDNSType_EID,			// 31 Endpoint identifier
    177 	kDNSType_NIMLOC,		// 32 Nimrod Locator
    178 	kDNSType_SRV,			// 33 Service record
    179 	kDNSType_ATMA,			// 34 ATM Address
    180 	kDNSType_NAPTR,			// 35 Naming Authority PoinTeR
    181 	kDNSType_KX,			// 36 Key Exchange
    182 	kDNSType_CERT,			// 37 Certification record
    183 	kDNSType_A6,			// 38 IPv6 Address (deprecated)
    184 	kDNSType_DNAME,			// 39 Non-terminal DNAME (for IPv6)
    185 	kDNSType_SINK,			// 40 Kitchen sink (experimental)
    186 	kDNSType_OPT,			// 41 EDNS0 option (meta-RR)
    187 	kDNSType_APL,			// 42 Address Prefix List
    188 	kDNSType_DS,			// 43 Delegation Signer
    189 	kDNSType_SSHFP,			// 44 SSH Key Fingerprint
    190 	kDNSType_IPSECKEY,		// 45 IPSECKEY
    191 	kDNSType_RRSIG,			// 46 RRSIG
    192 	kDNSType_NSEC,			// 47 Denial of Existence
    193 	kDNSType_DNSKEY,		// 48 DNSKEY
    194 	kDNSType_DHCID,			// 49 DHCP Client Identifier
    195 	kDNSType_NSEC3,			// 50 Hashed Authenticated Denial of Existence
    196 	kDNSType_NSEC3PARAM,	// 51 Hashed Authenticated Denial of Existence
    197 
    198 	kDNSType_HIP = 55,		// 55 Host Identity Protocol
    199 
    200 	kDNSType_SPF = 99,		// 99 Sender Policy Framework for E-Mail
    201 	kDNSType_UINFO,			// 100 IANA-Reserved
    202 	kDNSType_UID,			// 101 IANA-Reserved
    203 	kDNSType_GID,			// 102 IANA-Reserved
    204 	kDNSType_UNSPEC,		// 103 IANA-Reserved
    205 
    206 	kDNSType_TKEY = 249,	// 249 Transaction key
    207 	kDNSType_TSIG,			// 250 Transaction signature
    208 	kDNSType_IXFR,			// 251 Incremental zone transfer
    209 	kDNSType_AXFR,			// 252 Transfer zone of authority
    210 	kDNSType_MAILB,			// 253 Transfer mailbox records
    211 	kDNSType_MAILA,			// 254 Transfer mail agent records
    212 	kDNSQType_ANY			// Not a DNS type, but a DNS query type, meaning "all types"
    213 	} DNS_TypeValues;
    214 
    215 // ***************************************************************************
    216 #if 0
    217 #pragma mark -
    218 #pragma mark - Simple types
    219 #endif
    220 
    221 // mDNS defines its own names for these common types to simplify portability across
    222 // multiple platforms that may each have their own (different) names for these types.
    223 typedef          int   mDNSBool;
    224 typedef   signed char  mDNSs8;
    225 typedef unsigned char  mDNSu8;
    226 typedef   signed short mDNSs16;
    227 typedef unsigned short mDNSu16;
    228 
    229 // <http://gcc.gnu.org/onlinedocs/gcc-3.3.3/cpp/Common-Predefined-Macros.html> says
    230 //   __LP64__ _LP64
    231 //   These macros are defined, with value 1, if (and only if) the compilation is
    232 //   for a target where long int and pointer both use 64-bits and int uses 32-bit.
    233 // <http://www.intel.com/software/products/compilers/clin/docs/ug/lin1077.htm> says
    234 //   Macro Name __LP64__ Value 1
    235 // A quick Google search for "defined(__LP64__)" OR "#ifdef __LP64__" gives 2590 hits and
    236 // a search for "#if __LP64__" gives only 12, so I think we'll go with the majority and use defined()
    237 #if defined(_ILP64) || defined(__ILP64__)
    238 typedef   signed int32 mDNSs32;
    239 typedef unsigned int32 mDNSu32;
    240 #elif defined(_LP64) || defined(__LP64__)
    241 typedef   signed int   mDNSs32;
    242 typedef unsigned int   mDNSu32;
    243 #else
    244 typedef   signed long  mDNSs32;
    245 typedef unsigned long  mDNSu32;
    246 //typedef   signed int mDNSs32;
    247 //typedef unsigned int mDNSu32;
    248 #endif
    249 
    250 // To enforce useful type checking, we make mDNSInterfaceID be a pointer to a dummy struct
    251 // This way, mDNSInterfaceIDs can be assigned, and compared with each other, but not with other types
    252 // Declaring the type to be the typical generic "void *" would lack this type checking
    253 typedef struct mDNSInterfaceID_dummystruct { void *dummy; } *mDNSInterfaceID;
    254 
    255 // These types are for opaque two- and four-byte identifiers.
    256 // The "NotAnInteger" fields of the unions allow the value to be conveniently passed around in a
    257 // register for the sake of efficiency, and compared for equality or inequality, but don't forget --
    258 // just because it is in a register doesn't mean it is an integer. Operations like greater than,
    259 // less than, add, multiply, increment, decrement, etc., are undefined for opaque identifiers,
    260 // and if you make the mistake of trying to do those using the NotAnInteger field, then you'll
    261 // find you get code that doesn't work consistently on big-endian and little-endian machines.
    262 #if defined(_WIN32)
    263  #pragma pack(push,2)
    264 #endif
    265 typedef       union { mDNSu8 b[ 2]; mDNSu16 NotAnInteger; } mDNSOpaque16;
    266 typedef       union { mDNSu8 b[ 4]; mDNSu32 NotAnInteger; } mDNSOpaque32;
    267 typedef packedunion { mDNSu8 b[ 6]; mDNSu16 w[3]; mDNSu32 l[1]; } mDNSOpaque48;
    268 typedef       union { mDNSu8 b[ 8]; mDNSu16 w[4]; mDNSu32 l[2]; } mDNSOpaque64;
    269 typedef       union { mDNSu8 b[16]; mDNSu16 w[8]; mDNSu32 l[4]; } mDNSOpaque128;
    270 #if defined(_WIN32)
    271  #pragma pack(pop)
    272 #endif
    273 
    274 typedef mDNSOpaque16  mDNSIPPort;		// An IP port is a two-byte opaque identifier (not an integer)
    275 typedef mDNSOpaque32  mDNSv4Addr;		// An IP address is a four-byte opaque identifier (not an integer)
    276 typedef mDNSOpaque128 mDNSv6Addr;		// An IPv6 address is a 16-byte opaque identifier (not an integer)
    277 typedef mDNSOpaque48  mDNSEthAddr;		// An Ethernet address is a six-byte opaque identifier (not an integer)
    278 
    279 // Bit operations for opaque 64 bit quantity. Uses the 32 bit quantity(l[2]) to set and clear bits
    280 #define mDNSNBBY 8
    281 #define bit_set_opaque64(op64, index) (op64.l[((index))/(sizeof(mDNSu32) * mDNSNBBY)] |= (1 << ((index) % (sizeof(mDNSu32) * mDNSNBBY))))
    282 #define bit_clr_opaque64(op64, index) (op64.l[((index))/(sizeof(mDNSu32) * mDNSNBBY)] &= ~(1 << ((index) % (sizeof(mDNSu32) * mDNSNBBY))))
    283 #define bit_get_opaque64(op64, index) (op64.l[((index))/(sizeof(mDNSu32) * mDNSNBBY)] & (1 << ((index) % (sizeof(mDNSu32) * mDNSNBBY))))
    284 
    285 enum
    286 	{
    287 	mDNSAddrType_None    = 0,
    288 	mDNSAddrType_IPv4    = 4,
    289 	mDNSAddrType_IPv6    = 6,
    290 	mDNSAddrType_Unknown = ~0	// Special marker value used in known answer list recording
    291 	};
    292 
    293 enum
    294 	{
    295 	mDNSTransport_None = 0,
    296 	mDNSTransport_UDP  = 1,
    297 	mDNSTransport_TCP  = 2
    298 	};
    299 
    300 typedef struct
    301 	{
    302 	mDNSs32 type;
    303 	union { mDNSv6Addr v6; mDNSv4Addr v4; } ip;
    304 	} mDNSAddr;
    305 
    306 enum { mDNSfalse = 0, mDNStrue = 1 };
    307 
    308 #define mDNSNULL 0L
    309 
    310 enum
    311 	{
    312 	mStatus_Waiting           = 1,
    313 	mStatus_NoError           = 0,
    314 
    315 	// mDNS return values are in the range FFFE FF00 (-65792) to FFFE FFFF (-65537)
    316 	// The top end of the range (FFFE FFFF) is used for error codes;
    317 	// the bottom end of the range (FFFE FF00) is used for non-error values;
    318 
    319 	// Error codes:
    320 	mStatus_UnknownErr                = -65537,		// First value: 0xFFFE FFFF
    321 	mStatus_NoSuchNameErr             = -65538,
    322 	mStatus_NoMemoryErr               = -65539,
    323 	mStatus_BadParamErr               = -65540,
    324 	mStatus_BadReferenceErr           = -65541,
    325 	mStatus_BadStateErr               = -65542,
    326 	mStatus_BadFlagsErr               = -65543,
    327 	mStatus_UnsupportedErr            = -65544,
    328 	mStatus_NotInitializedErr         = -65545,
    329 	mStatus_NoCache                   = -65546,
    330 	mStatus_AlreadyRegistered         = -65547,
    331 	mStatus_NameConflict              = -65548,
    332 	mStatus_Invalid                   = -65549,
    333 	mStatus_Firewall                  = -65550,
    334 	mStatus_Incompatible              = -65551,
    335 	mStatus_BadInterfaceErr           = -65552,
    336 	mStatus_Refused                   = -65553,
    337 	mStatus_NoSuchRecord              = -65554,
    338 	mStatus_NoAuth                    = -65555,
    339 	mStatus_NoSuchKey                 = -65556,
    340 	mStatus_NATTraversal              = -65557,
    341 	mStatus_DoubleNAT                 = -65558,
    342 	mStatus_BadTime                   = -65559,
    343 	mStatus_BadSig                    = -65560,     // while we define this per RFC 2845, BIND 9 returns Refused for bad/missing signatures
    344 	mStatus_BadKey                    = -65561,
    345 	mStatus_TransientErr              = -65562,     // transient failures, e.g. sending packets shortly after a network transition or wake from sleep
    346 	mStatus_ServiceNotRunning         = -65563,     // Background daemon not running
    347 	mStatus_NATPortMappingUnsupported = -65564,     // NAT doesn't support NAT-PMP or UPnP
    348 	mStatus_NATPortMappingDisabled    = -65565,     // NAT supports NAT-PMP or UPnP but it's disabled by the administrator
    349 	mStatus_NoRouter                  = -65566,
    350 	mStatus_PollingMode               = -65567,
    351 	mStatus_Timeout                   = -65568,
    352 	// -65568 to -65786 currently unused; available for allocation
    353 
    354 	// tcp connection status
    355 	mStatus_ConnPending       = -65787,
    356 	mStatus_ConnFailed        = -65788,
    357 	mStatus_ConnEstablished   = -65789,
    358 
    359 	// Non-error values:
    360 	mStatus_GrowCache         = -65790,
    361 	mStatus_ConfigChanged     = -65791,
    362 	mStatus_MemFree           = -65792		// Last value: 0xFFFE FF00
    363 	// mStatus_MemFree is the last legal mDNS error code, at the end of the range allocated for mDNS
    364 	};
    365 
    366 typedef mDNSs32 mStatus;
    367 
    368 // RFC 1034/1035 specify that a domain label consists of a length byte plus up to 63 characters
    369 #define MAX_DOMAIN_LABEL 63
    370 typedef struct { mDNSu8 c[ 64]; } domainlabel;		// One label: length byte and up to 63 characters
    371 
    372 // RFC 1034/1035/2181 specify that a domain name (length bytes and data bytes) may be up to 255 bytes long,
    373 // plus the terminating zero at the end makes 256 bytes total in the on-the-wire format.
    374 #define MAX_DOMAIN_NAME 256
    375 typedef struct { mDNSu8 c[256]; } domainname;		// Up to 256 bytes of length-prefixed domainlabels
    376 
    377 typedef struct { mDNSu8 c[256]; } UTF8str255;		// Null-terminated C string
    378 
    379 // The longest legal textual form of a DNS name is 1009 bytes, including the C-string terminating NULL at the end.
    380 // Explanation:
    381 // When a native domainname object is converted to printable textual form using ConvertDomainNameToCString(),
    382 // non-printing characters are represented in the conventional DNS way, as '\ddd', where ddd is a three-digit decimal number.
    383 // The longest legal domain name is 256 bytes, in the form of four labels as shown below:
    384 // Length byte, 63 data bytes, length byte, 63 data bytes, length byte, 63 data bytes, length byte, 62 data bytes, zero byte.
    385 // Each label is encoded textually as characters followed by a trailing dot.
    386 // If every character has to be represented as a four-byte escape sequence, then this makes the maximum textual form four labels
    387 // plus the C-string terminating NULL as shown below:
    388 // 63*4+1 + 63*4+1 + 63*4+1 + 62*4+1 + 1 = 1009.
    389 // Note that MAX_ESCAPED_DOMAIN_LABEL is not normally used: If you're only decoding a single label, escaping is usually not required.
    390 // It is for domain names, where dots are used as label separators, that proper escaping is vital.
    391 #define MAX_ESCAPED_DOMAIN_LABEL 254
    392 #define MAX_ESCAPED_DOMAIN_NAME 1009
    393 
    394 // MAX_REVERSE_MAPPING_NAME
    395 // For IPv4: "123.123.123.123.in-addr.arpa."  30 bytes including terminating NUL
    396 // For IPv6: "x.x.x.x.x.x.x.x.x.x.x.x.x.x.x.x.x.x.x.x.x.x.x.x.x.x.x.x.x.x.x.x.ip6.arpa."  74 bytes including terminating NUL
    397 
    398 #define MAX_REVERSE_MAPPING_NAME_V4 30
    399 #define MAX_REVERSE_MAPPING_NAME_V6 74
    400 #define MAX_REVERSE_MAPPING_NAME    74
    401 
    402 // Most records have a TTL of 75 minutes, so that their 80% cache-renewal query occurs once per hour.
    403 // For records containing a hostname (in the name on the left, or in the rdata on the right),
    404 // like A, AAAA, reverse-mapping PTR, and SRV, we use a two-minute TTL by default, because we don't want
    405 // them to hang around for too long in the cache if the host in question crashes or otherwise goes away.
    406 
    407 #define kStandardTTL (3600UL * 100 / 80)
    408 #define kHostNameTTL 120UL
    409 
    410 // Some applications want to register their SRV records with a lower ttl so that in case the server
    411 // using a dynamic port number restarts, the clients will not have stale information for more than
    412 // 10 seconds
    413 
    414 #define kHostNameSmallTTL 10UL
    415 
    416 
    417 // Multicast DNS uses announcements (gratuitous responses) to update peer caches.
    418 // This means it is feasible to use relatively larger TTL values than we might otherwise
    419 // use, because we have a cache coherency protocol to keep the peer caches up to date.
    420 // With Unicast DNS, once an authoritative server gives a record with a certain TTL value to a client
    421 // or caching server, that client or caching server is entitled to hold onto the record until its TTL
    422 // expires, and has no obligation to contact the authoritative server again until that time arrives.
    423 // This means that whereas Multicast DNS can use announcements to pre-emptively update stale data
    424 // before it would otherwise have expired, standard Unicast DNS (not using LLQs) has no equivalent
    425 // mechanism, and TTL expiry is the *only* mechanism by which stale data gets deleted. Because of this,
    426 // we currently limit the TTL to ten seconds in such cases where no dynamic cache updating is possible.
    427 #define kStaticCacheTTL 10
    428 
    429 #define DefaultTTLforRRType(X) (((X) == kDNSType_A || (X) == kDNSType_AAAA || (X) == kDNSType_SRV) ? kHostNameTTL : kStandardTTL)
    430 
    431 typedef struct AuthRecord_struct AuthRecord;
    432 typedef struct ServiceRecordSet_struct ServiceRecordSet;
    433 typedef struct CacheRecord_struct CacheRecord;
    434 typedef struct CacheGroup_struct CacheGroup;
    435 typedef struct AuthGroup_struct AuthGroup;
    436 typedef struct DNSQuestion_struct DNSQuestion;
    437 typedef struct ZoneData_struct ZoneData;
    438 typedef struct mDNS_struct mDNS;
    439 typedef struct mDNS_PlatformSupport_struct mDNS_PlatformSupport;
    440 typedef struct NATTraversalInfo_struct NATTraversalInfo;
    441 
    442 // Structure to abstract away the differences between TCP/SSL sockets, and one for UDP sockets
    443 // The actual definition of these structures appear in the appropriate platform support code
    444 typedef struct TCPSocket_struct TCPSocket;
    445 typedef struct UDPSocket_struct UDPSocket;
    446 
    447 // ***************************************************************************
    448 #if 0
    449 #pragma mark -
    450 #pragma mark - DNS Message structures
    451 #endif
    452 
    453 #define mDNS_numZones   numQuestions
    454 #define mDNS_numPrereqs numAnswers
    455 #define mDNS_numUpdates numAuthorities
    456 
    457 typedef packedstruct
    458 	{
    459 	mDNSOpaque16 id;
    460 	mDNSOpaque16 flags;
    461 	mDNSu16 numQuestions;
    462 	mDNSu16 numAnswers;
    463 	mDNSu16 numAuthorities;
    464 	mDNSu16 numAdditionals;
    465 	} DNSMessageHeader;
    466 
    467 // We can send and receive packets up to 9000 bytes (Ethernet Jumbo Frame size, if that ever becomes widely used)
    468 // However, in the normal case we try to limit packets to 1500 bytes so that we don't get IP fragmentation on standard Ethernet
    469 // 40 (IPv6 header) + 8 (UDP header) + 12 (DNS message header) + 1440 (DNS message body) = 1500 total
    470 #define AbsoluteMaxDNSMessageData 8940
    471 #define NormalMaxDNSMessageData 1440
    472 typedef packedstruct
    473 	{
    474 	DNSMessageHeader h;						// Note: Size 12 bytes
    475 	mDNSu8 data[AbsoluteMaxDNSMessageData];	// 40 (IPv6) + 8 (UDP) + 12 (DNS header) + 8940 (data) = 9000
    476 	} DNSMessage;
    477 
    478 typedef struct tcpInfo_t
    479 	{
    480 	mDNS             *m;
    481 	TCPSocket        *sock;
    482 	DNSMessage        request;
    483 	int               requestLen;
    484 	DNSQuestion      *question;   // For queries
    485 	AuthRecord       *rr;         // For record updates
    486 	mDNSAddr          Addr;
    487 	mDNSIPPort        Port;
    488 	mDNSIPPort        SrcPort;
    489 	DNSMessage       *reply;
    490 	mDNSu16           replylen;
    491 	unsigned long     nread;
    492 	int               numReplies;
    493 	} tcpInfo_t;
    494 
    495 // ***************************************************************************
    496 #if 0
    497 #pragma mark -
    498 #pragma mark - Other Packet Format Structures
    499 #endif
    500 
    501 typedef packedstruct
    502 	{
    503 	mDNSEthAddr  dst;
    504 	mDNSEthAddr  src;
    505 	mDNSOpaque16 ethertype;
    506 	} EthernetHeader;		// 14 bytes
    507 
    508 typedef packedstruct
    509 	{
    510 	mDNSOpaque16 hrd;
    511 	mDNSOpaque16 pro;
    512 	mDNSu8       hln;
    513 	mDNSu8       pln;
    514 	mDNSOpaque16 op;
    515 	mDNSEthAddr  sha;
    516 	mDNSv4Addr   spa;
    517 	mDNSEthAddr  tha;
    518 	mDNSv4Addr   tpa;
    519 	} ARP_EthIP;			// 28 bytes
    520 
    521 typedef packedstruct
    522 	{
    523 	mDNSu8       vlen;
    524 	mDNSu8       tos;
    525 	mDNSu16      totlen;
    526 	mDNSOpaque16 id;
    527 	mDNSOpaque16 flagsfrags;
    528 	mDNSu8       ttl;
    529 	mDNSu8       protocol;	// Payload type: 0x06 = TCP, 0x11 = UDP
    530 	mDNSu16      checksum;
    531 	mDNSv4Addr   src;
    532 	mDNSv4Addr   dst;
    533 	} IPv4Header;			// 20 bytes
    534 
    535 typedef packedstruct
    536 	{
    537 	mDNSu32      vcf;		// Version, Traffic Class, Flow Label
    538 	mDNSu16      len;		// Payload Length
    539 	mDNSu8       pro;		// Type of next header: 0x06 = TCP, 0x11 = UDP, 0x3A = ICMPv6
    540 	mDNSu8       ttl;		// Hop Limit
    541 	mDNSv6Addr   src;
    542 	mDNSv6Addr   dst;
    543 	} IPv6Header;			// 40 bytes
    544 
    545 typedef packedstruct
    546 	{
    547 	mDNSv6Addr   src;
    548 	mDNSv6Addr   dst;
    549 	mDNSOpaque32 len;
    550 	mDNSOpaque32 pro;
    551 	} IPv6PseudoHeader;		// 40 bytes
    552 
    553 typedef union
    554 	{
    555 	mDNSu8       bytes[20];
    556 	ARP_EthIP    arp;
    557 	IPv4Header   v4;
    558 	IPv6Header   v6;
    559 	} NetworkLayerPacket;
    560 
    561 typedef packedstruct
    562 	{
    563 	mDNSIPPort   src;
    564 	mDNSIPPort   dst;
    565 	mDNSu32      seq;
    566 	mDNSu32      ack;
    567 	mDNSu8       offset;
    568 	mDNSu8       flags;
    569 	mDNSu16      window;
    570 	mDNSu16      checksum;
    571 	mDNSu16      urgent;
    572 	} TCPHeader;			// 20 bytes; IP protocol type 0x06
    573 
    574 typedef packedstruct
    575 	{
    576 	mDNSIPPort   src;
    577 	mDNSIPPort   dst;
    578 	mDNSu16      len;		// Length including UDP header (i.e. minimum value is 8 bytes)
    579 	mDNSu16      checksum;
    580 	} UDPHeader;			// 8 bytes; IP protocol type 0x11
    581 
    582 typedef packedstruct
    583 	{
    584 	mDNSu8       type;		// 0x87 == Neighbor Solicitation, 0x88 == Neighbor Advertisement
    585 	mDNSu8       code;
    586 	mDNSu16      checksum;
    587 	mDNSu32      flags_res;	// R/S/O flags and reserved bits
    588 	mDNSv6Addr   target;
    589 	// Typically 8 bytes of options are also present
    590 	} IPv6NDP;				// 24 bytes or more; IP protocol type 0x3A
    591 
    592 #define NDP_Sol 0x87
    593 #define NDP_Adv 0x88
    594 
    595 #define NDP_Router    0x80
    596 #define NDP_Solicited 0x40
    597 #define NDP_Override  0x20
    598 
    599 #define NDP_SrcLL 1
    600 #define NDP_TgtLL 2
    601 
    602 typedef union
    603 	{
    604 	mDNSu8       bytes[20];
    605 	TCPHeader    tcp;
    606 	UDPHeader    udp;
    607 	IPv6NDP      ndp;
    608 	} TransportLayerPacket;
    609 
    610 typedef packedstruct
    611 	{
    612 	mDNSOpaque64 InitiatorCookie;
    613 	mDNSOpaque64 ResponderCookie;
    614 	mDNSu8       NextPayload;
    615 	mDNSu8       Version;
    616 	mDNSu8       ExchangeType;
    617 	mDNSu8       Flags;
    618 	mDNSOpaque32 MessageID;
    619 	mDNSu32      Length;
    620 	} IKEHeader;			// 28 bytes
    621 
    622 // ***************************************************************************
    623 #if 0
    624 #pragma mark -
    625 #pragma mark - Resource Record structures
    626 #endif
    627 
    628 // Authoritative Resource Records:
    629 // There are four basic types: Shared, Advisory, Unique, Known Unique
    630 
    631 // * Shared Resource Records do not have to be unique
    632 // -- Shared Resource Records are used for DNS-SD service PTRs
    633 // -- It is okay for several hosts to have RRs with the same name but different RDATA
    634 // -- We use a random delay on responses to reduce collisions when all the hosts respond to the same query
    635 // -- These RRs typically have moderately high TTLs (e.g. one hour)
    636 // -- These records are announced on startup and topology changes for the benefit of passive listeners
    637 // -- These records send a goodbye packet when deregistering
    638 //
    639 // * Advisory Resource Records are like Shared Resource Records, except they don't send a goodbye packet
    640 //
    641 // * Unique Resource Records should be unique among hosts within any given mDNS scope
    642 // -- The majority of Resource Records are of this type
    643 // -- If two entities on the network have RRs with the same name but different RDATA, this is a conflict
    644 // -- Responses may be sent immediately, because only one host should be responding to any particular query
    645 // -- These RRs typically have low TTLs (e.g. a few minutes)
    646 // -- On startup and after topology changes, a host issues queries to verify uniqueness
    647 
    648 // * Known Unique Resource Records are treated like Unique Resource Records, except that mDNS does
    649 // not have to verify their uniqueness because this is already known by other means (e.g. the RR name
    650 // is derived from the host's IP or Ethernet address, which is already known to be a unique identifier).
    651 
    652 // Summary of properties of different record types:
    653 // Probe?    Does this record type send probes before announcing?
    654 // Conflict? Does this record type react if we observe an apparent conflict?
    655 // Goodbye?  Does this record type send a goodbye packet on departure?
    656 //
    657 //               Probe? Conflict? Goodbye? Notes
    658 // Unregistered                            Should not appear in any list (sanity check value)
    659 // Shared         No      No       Yes     e.g. Service PTR record
    660 // Deregistering  No      No       Yes     Shared record about to announce its departure and leave the list
    661 // Advisory       No      No       No
    662 // Unique         Yes     Yes      No      Record intended to be unique -- will probe to verify
    663 // Verified       Yes     Yes      No      Record has completed probing, and is verified unique
    664 // KnownUnique    No      Yes      No      Record is assumed by other means to be unique
    665 
    666 // Valid lifecycle of a record:
    667 // Unregistered ->                   Shared      -> Deregistering -(goodbye)-> Unregistered
    668 // Unregistered ->                   Advisory                               -> Unregistered
    669 // Unregistered -> Unique -(probe)-> Verified                               -> Unregistered
    670 // Unregistered ->                   KnownUnique                            -> Unregistered
    671 
    672 // Each Authoritative kDNSRecordType has only one bit set. This makes it easy to quickly see if a record
    673 // is one of a particular set of types simply by performing the appropriate bitwise masking operation.
    674 
    675 // Cache Resource Records (received from the network):
    676 // There are four basic types: Answer, Unique Answer, Additional, Unique Additional
    677 // Bit 7 (the top bit) of kDNSRecordType is always set for Cache Resource Records; always clear for Authoritative Resource Records
    678 // Bit 6 (value 0x40) is set for answer records; clear for authority/additional records
    679 // Bit 5 (value 0x20) is set for records received with the kDNSClass_UniqueRRSet
    680 
    681 enum
    682 	{
    683 	kDNSRecordTypeUnregistered     = 0x00,	// Not currently in any list
    684 	kDNSRecordTypeDeregistering    = 0x01,	// Shared record about to announce its departure and leave the list
    685 
    686 	kDNSRecordTypeUnique           = 0x02,	// Will become a kDNSRecordTypeVerified when probing is complete
    687 
    688 	kDNSRecordTypeAdvisory         = 0x04,	// Like Shared, but no goodbye packet
    689 	kDNSRecordTypeShared           = 0x08,	// Shared means record name does not have to be unique -- use random delay on responses
    690 
    691 	kDNSRecordTypeVerified         = 0x10,	// Unique means mDNS should check that name is unique (and then send immediate responses)
    692 	kDNSRecordTypeKnownUnique      = 0x20,	// Known Unique means mDNS can assume name is unique without checking
    693 	                                        // For Dynamic Update records, Known Unique means the record must already exist on the server.
    694 	kDNSRecordTypeUniqueMask       = (kDNSRecordTypeUnique | kDNSRecordTypeVerified | kDNSRecordTypeKnownUnique),
    695 	kDNSRecordTypeActiveSharedMask = (kDNSRecordTypeAdvisory         | kDNSRecordTypeShared),
    696 	kDNSRecordTypeActiveUniqueMask = (kDNSRecordTypeVerified         | kDNSRecordTypeKnownUnique),
    697 	kDNSRecordTypeActiveMask       = (kDNSRecordTypeActiveSharedMask | kDNSRecordTypeActiveUniqueMask),
    698 
    699 	kDNSRecordTypePacketAdd        = 0x80,	// Received in the Additional  Section of a DNS Response
    700 	kDNSRecordTypePacketAddUnique  = 0x90,	// Received in the Additional  Section of a DNS Response with kDNSClass_UniqueRRSet set
    701 	kDNSRecordTypePacketAuth       = 0xA0,	// Received in the Authorities Section of a DNS Response
    702 	kDNSRecordTypePacketAuthUnique = 0xB0,	// Received in the Authorities Section of a DNS Response with kDNSClass_UniqueRRSet set
    703 	kDNSRecordTypePacketAns        = 0xC0,	// Received in the Answer      Section of a DNS Response
    704 	kDNSRecordTypePacketAnsUnique  = 0xD0,	// Received in the Answer      Section of a DNS Response with kDNSClass_UniqueRRSet set
    705 
    706 	kDNSRecordTypePacketNegative   = 0xF0,	// Pseudo-RR generated to cache non-existence results like NXDomain
    707 
    708 	kDNSRecordTypePacketUniqueMask = 0x10	// True for PacketAddUnique, PacketAnsUnique, PacketAuthUnique, kDNSRecordTypePacketNegative
    709 	};
    710 
    711 typedef packedstruct { mDNSu16 priority; mDNSu16 weight; mDNSIPPort port; domainname target;   } rdataSRV;
    712 typedef packedstruct { mDNSu16 preference;                                domainname exchange; } rdataMX;
    713 typedef packedstruct { domainname mbox; domainname txt;                                        } rdataRP;
    714 typedef packedstruct { mDNSu16 preference; domainname map822; domainname mapx400;              } rdataPX;
    715 
    716 typedef packedstruct
    717 	{
    718 	domainname mname;
    719 	domainname rname;
    720 	mDNSs32 serial;		// Modular counter; increases when zone changes
    721 	mDNSu32 refresh;	// Time in seconds that a slave waits after successful replication of the database before it attempts replication again
    722 	mDNSu32 retry;		// Time in seconds that a slave waits after an unsuccessful replication attempt before it attempts replication again
    723 	mDNSu32 expire;		// Time in seconds that a slave holds on to old data while replication attempts remain unsuccessful
    724 	mDNSu32 min;		// Nominally the minimum record TTL for this zone, in seconds; also used for negative caching.
    725 	} rdataSOA;
    726 
    727 // EDNS Option Code registrations are recorded in the "DNS EDNS0 Options" section of
    728 // <http://www.iana.org/assignments/dns-parameters>
    729 
    730 #define kDNSOpt_LLQ   1
    731 #define kDNSOpt_Lease 2
    732 #define kDNSOpt_NSID  3
    733 #define kDNSOpt_Owner 4
    734 
    735 typedef struct
    736 	{
    737 	mDNSu16      vers;
    738 	mDNSu16      llqOp;
    739 	mDNSu16      err;	// Or UDP reply port, in setup request
    740 	// Note: In the in-memory form, there's typically a two-byte space here, so that the following 64-bit id is word-aligned
    741 	mDNSOpaque64 id;
    742 	mDNSu32      llqlease;
    743 	} LLQOptData;
    744 
    745 typedef struct
    746 	{
    747 	mDNSu8       vers;		// Version number of this Owner OPT record
    748 	mDNSs8       seq;		// Sleep/wake epoch
    749 	mDNSEthAddr  HMAC;		// Host's primary identifier (e.g. MAC of on-board Ethernet)
    750 	mDNSEthAddr  IMAC;		// Interface's MAC address (if different to primary MAC)
    751 	mDNSOpaque48 password;	// Optional password
    752 	} OwnerOptData;
    753 
    754 // Note: rdataOPT format may be repeated an arbitrary number of times in a single resource record
    755 typedef packedstruct
    756 	{
    757 	mDNSu16 opt;
    758 	mDNSu16 optlen;
    759 	union { LLQOptData llq; mDNSu32 updatelease; OwnerOptData owner; } u;
    760 	} rdataOPT;
    761 
    762 // Space needed to put OPT records into a packet:
    763 // Header      11 bytes (name 1, type 2, class 2, TTL 4, length 2)
    764 // LLQ rdata   18 bytes (opt 2, len 2, vers 2, op 2, err 2, id 8, lease 4)
    765 // Lease rdata  8 bytes (opt 2, len 2, lease 4)
    766 // Owner rdata 12-24    (opt 2, len 2, owner 8-20)
    767 
    768 #define DNSOpt_Header_Space                 11
    769 #define DNSOpt_LLQData_Space               (4 + 2 + 2 + 2 + 8 + 4)
    770 #define DNSOpt_LeaseData_Space             (4 + 4)
    771 #define DNSOpt_OwnerData_ID_Space          (4 + 2 + 6)
    772 #define DNSOpt_OwnerData_ID_Wake_Space     (4 + 2 + 6 + 6)
    773 #define DNSOpt_OwnerData_ID_Wake_PW4_Space (4 + 2 + 6 + 6 + 4)
    774 #define DNSOpt_OwnerData_ID_Wake_PW6_Space (4 + 2 + 6 + 6 + 6)
    775 
    776 #define ValidOwnerLength(X) (	(X) == DNSOpt_OwnerData_ID_Space          - 4 || \
    777 								(X) == DNSOpt_OwnerData_ID_Wake_Space     - 4 || \
    778 								(X) == DNSOpt_OwnerData_ID_Wake_PW4_Space - 4 || \
    779 								(X) == DNSOpt_OwnerData_ID_Wake_PW6_Space - 4    )
    780 
    781 #define DNSOpt_Owner_Space(A,B) (mDNSSameEthAddress((A),(B)) ? DNSOpt_OwnerData_ID_Space : DNSOpt_OwnerData_ID_Wake_Space)
    782 
    783 #define DNSOpt_Data_Space(O) (                                  \
    784 	(O)->opt == kDNSOpt_LLQ   ? DNSOpt_LLQData_Space   :        \
    785 	(O)->opt == kDNSOpt_Lease ? DNSOpt_LeaseData_Space :        \
    786 	(O)->opt == kDNSOpt_Owner ? DNSOpt_Owner_Space(&(O)->u.owner.HMAC, &(O)->u.owner.IMAC) : 0x10000)
    787 
    788 // A maximal NSEC record is:
    789 //   256 bytes domainname 'nextname'
    790 // + 256 * 34 = 8704 bytes of bitmap data
    791 // = 8960 bytes total
    792 // For now we only support NSEC records encoding DNS types 0-255 and ignore the nextname (we always set it to be the same as the rrname),
    793 // which gives us a fixed in-memory size of 32 bytes (256 bits)
    794 typedef struct
    795 	{
    796 	mDNSu8 bitmap[32];
    797 	} rdataNSEC;
    798 
    799 // StandardAuthRDSize is 264 (256+8), which is large enough to hold a maximum-sized SRV record (6 + 256 bytes)
    800 // MaximumRDSize is 8K the absolute maximum we support (at least for now)
    801 #define StandardAuthRDSize 264
    802 #define MaximumRDSize 8192
    803 
    804 // InlineCacheRDSize is 68
    805 // Records received from the network with rdata this size or less have their rdata stored right in the CacheRecord object
    806 // Records received from the network with rdata larger than this have additional storage allocated for the rdata
    807 // A quick unscientific sample from a busy network at Apple with lots of machines revealed this:
    808 // 1461 records in cache
    809 // 292 were one-byte TXT records
    810 // 136 were four-byte A records
    811 // 184 were sixteen-byte AAAA records
    812 // 780 were various PTR, TXT and SRV records from 12-64 bytes
    813 // Only 69 records had rdata bigger than 64 bytes
    814 // Note that since CacheRecord object and a CacheGroup object are allocated out of the same pool, it's sensible to
    815 // have them both be the same size. Making one smaller without making the other smaller won't actually save any memory.
    816 #define InlineCacheRDSize 68
    817 
    818 // On 64-bit, the pointers in a CacheRecord are bigger, and that creates 8 bytes more space for the name in a CacheGroup
    819 #if ENABLE_MULTI_PACKET_QUERY_SNOOPING
    820 	#if defined(_ILP64) || defined(__ILP64__) || defined(_LP64) || defined(__LP64__) || defined(_WIN64)
    821 	#define InlineCacheGroupNameSize 160
    822 	#else
    823 	#define InlineCacheGroupNameSize 148
    824 	#endif
    825 #else
    826 	#if defined(_ILP64) || defined(__ILP64__) || defined(_LP64) || defined(__LP64__) || defined(_WIN64)
    827 	#define InlineCacheGroupNameSize 144
    828 	#else
    829 	#define InlineCacheGroupNameSize 132
    830 	#endif
    831 #endif
    832 
    833 // The RDataBody union defines the common rdata types that fit into our 264-byte limit
    834 typedef union
    835 	{
    836 	mDNSu8      data[StandardAuthRDSize];
    837 	mDNSv4Addr  ipv4;		// For 'A' record
    838 	domainname  name;		// For PTR, NS, CNAME, DNAME
    839 	UTF8str255  txt;
    840 	rdataMX     mx;
    841 	mDNSv6Addr  ipv6;		// For 'AAAA' record
    842 	rdataSRV    srv;
    843 	rdataOPT    opt[2];		// For EDNS0 OPT record; RDataBody may contain multiple variable-length rdataOPT objects packed together
    844 	rdataNSEC   nsec;
    845 	} RDataBody;
    846 
    847 // The RDataBody2 union is the same as above, except it includes fields for the larger types like soa, rp, px
    848 typedef union
    849 	{
    850 	mDNSu8      data[StandardAuthRDSize];
    851 	mDNSv4Addr  ipv4;		// For 'A' record
    852 	domainname  name;		// For PTR, NS, CNAME, DNAME
    853 	rdataSOA    soa;		// This is large; not included in the normal RDataBody definition
    854 	UTF8str255  txt;
    855 	rdataMX     mx;
    856 	rdataRP     rp;			// This is large; not included in the normal RDataBody definition
    857 	rdataPX     px;			// This is large; not included in the normal RDataBody definition
    858 	mDNSv6Addr  ipv6;		// For 'AAAA' record
    859 	rdataSRV    srv;
    860 	rdataOPT    opt[2];		// For EDNS0 OPT record; RDataBody may contain multiple variable-length rdataOPT objects packed together
    861 	rdataNSEC   nsec;
    862 	} RDataBody2;
    863 
    864 typedef struct
    865 	{
    866 	mDNSu16    MaxRDLength;	// Amount of storage allocated for rdata (usually sizeof(RDataBody))
    867 	mDNSu16    padding;		// So that RDataBody is aligned on 32-bit boundary
    868 	RDataBody  u;
    869 	} RData;
    870 
    871 // sizeofRDataHeader should be 4 bytes
    872 #define sizeofRDataHeader (sizeof(RData) - sizeof(RDataBody))
    873 
    874 // RData_small is a smaller version of the RData object, used for inline data storage embedded in a CacheRecord_struct
    875 typedef struct
    876 	{
    877 	mDNSu16    MaxRDLength;	// Storage allocated for data (may be greater than InlineCacheRDSize if additional storage follows this object)
    878 	mDNSu16    padding;		// So that data is aligned on 32-bit boundary
    879 	mDNSu8     data[InlineCacheRDSize];
    880 	} RData_small;
    881 
    882 // Note: Within an mDNSRecordCallback mDNS all API calls are legal except mDNS_Init(), mDNS_Exit(), mDNS_Execute()
    883 typedef void mDNSRecordCallback(mDNS *const m, AuthRecord *const rr, mStatus result);
    884 
    885 // Note:
    886 // Restrictions: An mDNSRecordUpdateCallback may not make any mDNS API calls.
    887 // The intent of this callback is to allow the client to free memory, if necessary.
    888 // The internal data structures of the mDNS code may not be in a state where mDNS API calls may be made safely.
    889 typedef void mDNSRecordUpdateCallback(mDNS *const m, AuthRecord *const rr, RData *OldRData, mDNSu16 OldRDLen);
    890 
    891 // ***************************************************************************
    892 #if 0
    893 #pragma mark -
    894 #pragma mark - NAT Traversal structures and constants
    895 #endif
    896 
    897 #define NATMAP_MAX_RETRY_INTERVAL    ((mDNSPlatformOneSecond * 60) * 15)    // Max retry interval is 15 minutes
    898 #define NATMAP_MIN_RETRY_INTERVAL     (mDNSPlatformOneSecond * 2)           // Min retry interval is 2 seconds
    899 #define NATMAP_INIT_RETRY             (mDNSPlatformOneSecond / 4)           // start at 250ms w/ exponential decay
    900 #define NATMAP_DEFAULT_LEASE          (60 * 60 * 2)                         // 2 hour lease life in seconds
    901 #define NATMAP_VERS 0
    902 
    903 typedef enum
    904 	{
    905 	NATOp_AddrRequest    = 0,
    906 	NATOp_MapUDP         = 1,
    907 	NATOp_MapTCP         = 2,
    908 
    909 	NATOp_AddrResponse   = 0x80 | 0,
    910 	NATOp_MapUDPResponse = 0x80 | 1,
    911 	NATOp_MapTCPResponse = 0x80 | 2,
    912 	} NATOp_t;
    913 
    914 enum
    915 	{
    916 	NATErr_None    = 0,
    917 	NATErr_Vers    = 1,
    918 	NATErr_Refused = 2,
    919 	NATErr_NetFail = 3,
    920 	NATErr_Res     = 4,
    921 	NATErr_Opcode  = 5
    922 	};
    923 
    924 typedef mDNSu16 NATErr_t;
    925 
    926 typedef packedstruct
    927 	{
    928 	mDNSu8 vers;
    929 	mDNSu8 opcode;
    930 	} NATAddrRequest;
    931 
    932 typedef packedstruct
    933 	{
    934 	mDNSu8     vers;
    935 	mDNSu8     opcode;
    936 	mDNSu16    err;
    937 	mDNSu32    upseconds;		// Time since last NAT engine reboot, in seconds
    938 	mDNSv4Addr ExtAddr;
    939 	} NATAddrReply;
    940 
    941 typedef packedstruct
    942 	{
    943 	mDNSu8 vers;
    944 	mDNSu8 opcode;
    945 	mDNSOpaque16 unused;
    946 	mDNSIPPort intport;
    947 	mDNSIPPort extport;
    948 	mDNSu32    NATReq_lease;
    949 	} NATPortMapRequest;
    950 
    951 typedef packedstruct
    952 	{
    953 	mDNSu8     vers;
    954 	mDNSu8     opcode;
    955 	mDNSu16    err;
    956 	mDNSu32    upseconds;		// Time since last NAT engine reboot, in seconds
    957 	mDNSIPPort intport;
    958 	mDNSIPPort extport;
    959 	mDNSu32    NATRep_lease;
    960 	} NATPortMapReply;
    961 
    962 typedef enum
    963 	{
    964 	LNTDiscoveryOp      = 1,
    965 	LNTExternalAddrOp   = 2,
    966 	LNTPortMapOp        = 3,
    967 	LNTPortMapDeleteOp  = 4
    968 	} LNTOp_t;
    969 
    970 #define LNT_MAXBUFSIZE 8192
    971 typedef struct tcpLNTInfo_struct tcpLNTInfo;
    972 struct tcpLNTInfo_struct
    973 	{
    974 	tcpLNTInfo       *next;
    975 	mDNS             *m;
    976 	NATTraversalInfo *parentNATInfo;	// pointer back to the parent NATTraversalInfo
    977 	TCPSocket        *sock;
    978 	LNTOp_t           op;				// operation performed using this connection
    979 	mDNSAddr          Address;			// router address
    980 	mDNSIPPort        Port;				// router port
    981 	mDNSu8           *Request;			// xml request to router
    982 	int               requestLen;
    983 	mDNSu8           *Reply;			// xml reply from router
    984 	int               replyLen;
    985 	unsigned long     nread;			// number of bytes read so far
    986 	int               retries;			// number of times we've tried to do this port mapping
    987 	};
    988 
    989 typedef void (*NATTraversalClientCallback)(mDNS *m, NATTraversalInfo *n);
    990 
    991 // if m->timenow <  ExpiryTime then we have an active mapping, and we'll renew halfway to expiry
    992 // if m->timenow >= ExpiryTime then our mapping has expired, and we're trying to create one
    993 
    994 struct NATTraversalInfo_struct
    995 	{
    996 	// Internal state fields. These are used internally by mDNSCore; the client layer needn't be concerned with them.
    997 	NATTraversalInfo           *next;
    998 
    999 	mDNSs32                     ExpiryTime;			// Time this mapping expires, or zero if no mapping
   1000 	mDNSs32                     retryInterval;		// Current interval, between last packet we sent and the next one
   1001 	mDNSs32                     retryPortMap;		// If Protocol is nonzero, time to send our next mapping packet
   1002 	mStatus                     NewResult;			// New error code; will be copied to Result just prior to invoking callback
   1003 
   1004 #ifdef _LEGACY_NAT_TRAVERSAL_
   1005 	tcpLNTInfo                  tcpInfo;			// Legacy NAT traversal (UPnP) TCP connection
   1006 #endif
   1007 
   1008 	// Result fields: When the callback is invoked these fields contain the answers the client is looking for
   1009 	// When the callback is invoked ExternalPort is *usually* set to be the same the same as RequestedPort, except:
   1010 	// (a) When we're behind a NAT gateway with port mapping disabled, ExternalPort is reported as zero to
   1011 	//     indicate that we don't currently have a working mapping (but RequestedPort retains the external port
   1012 	//     we'd like to get, the next time we meet an accomodating NAT gateway willing to give us one).
   1013 	// (b) When we have a routable non-RFC1918 address, we don't *need* a port mapping, so ExternalPort
   1014 	//     is reported as the same as our InternalPort, since that is effectively our externally-visible port too.
   1015 	//     Again, RequestedPort retains the external port we'd like to get the next time we find ourself behind a NAT gateway.
   1016 	// To improve stability of port mappings, RequestedPort is updated any time we get a successful
   1017 	// mapping response from the NAT-PMP or UPnP gateway. For example, if we ask for port 80, and
   1018 	// get assigned port 81, then thereafter we'll contine asking for port 81.
   1019 	mDNSInterfaceID             InterfaceID;
   1020 	mDNSv4Addr                  ExternalAddress;	// Initially set to onesIPv4Addr, until first callback
   1021 	mDNSIPPort                  ExternalPort;
   1022 	mDNSu32                     Lifetime;
   1023 	mStatus                     Result;
   1024 
   1025 	// Client API fields: The client must set up these fields *before* making any NAT traversal API calls
   1026 	mDNSu8                      Protocol;			// NATOp_MapUDP or NATOp_MapTCP, or zero if just requesting the external IP address
   1027 	mDNSIPPort                  IntPort;			// Client's internal port number (doesn't change)
   1028 	mDNSIPPort                  RequestedPort;		// Requested external port; may be updated with actual value assigned by gateway
   1029 	mDNSu32                     NATLease;			// Requested lifetime in seconds (doesn't change)
   1030 	NATTraversalClientCallback  clientCallback;
   1031 	void                       *clientContext;
   1032 	};
   1033 
   1034 enum
   1035 	{
   1036 	DNSServer_Untested = 0,
   1037 	DNSServer_Passed   = 1,
   1038 	DNSServer_Failed   = 2,
   1039 	DNSServer_Disabled = 3
   1040 	};
   1041 
   1042 enum
   1043 	{
   1044 	DNSServer_FlagDelete = 1,
   1045 	DNSServer_FlagNew    = 2
   1046 	};
   1047 
   1048 enum
   1049 	{
   1050 	McastResolver_FlagDelete = 1,
   1051 	McastResolver_FlagNew    = 2
   1052 	};
   1053 
   1054 typedef struct McastResolver
   1055 	{
   1056 	struct McastResolver *next;
   1057 	mDNSInterfaceID interface;
   1058 	mDNSu32         flags;		// Set when we're planning to delete this from the list
   1059 	domainname      domain;
   1060 	mDNSu32         timeout;	// timeout value for questions
   1061 	} McastResolver;
   1062 
   1063 typedef struct DNSServer
   1064 	{
   1065 	struct DNSServer *next;
   1066 	mDNSInterfaceID interface;	// For specialized uses; we can have DNS servers reachable over specific interfaces
   1067 	mDNSAddr        addr;
   1068 	mDNSIPPort      port;
   1069 	mDNSOpaque16    testid;
   1070 	mDNSu32         flags;		// Set when we're planning to delete this from the list
   1071 	mDNSu32         teststate;	// Have we sent bug-detection query to this server?
   1072 	mDNSs32         lasttest;	// Time we sent last bug-detection query to this server
   1073 	domainname      domain;		// name->server matching for "split dns"
   1074 	mDNSs32			penaltyTime; // amount of time this server is penalized
   1075 	mDNSBool		scoped;		// interface should be matched against question only
   1076 								// if scoped is set
   1077 	mDNSu32			timeout;	// timeout value for questions
   1078 	} DNSServer;
   1079 
   1080 typedef struct							// Size is 36 bytes when compiling for 32-bit; 48 when compiling for 64-bit
   1081 	{
   1082 	mDNSu8           RecordType;		// See enum above
   1083 	mDNSu16          rrtype;
   1084 	mDNSu16          rrclass;
   1085 	mDNSu32          rroriginalttl;		// In seconds
   1086 	mDNSu16          rdlength;			// Size of the raw rdata, in bytes, in the on-the-wire format
   1087 										// (In-memory storage may be larger, for structures containing 'holes', like SOA,
   1088 										// or smaller, for NSEC where we don't bother storing the nextname field)
   1089 	mDNSu16          rdestimate;		// Upper bound on on-the-wire size of rdata after name compression
   1090 	mDNSu32          namehash;			// Name-based (i.e. case-insensitive) hash of name
   1091 	mDNSu32          rdatahash;			// For rdata containing domain name (e.g. PTR, SRV, CNAME etc.), case-insensitive name hash
   1092 										// else, for all other rdata, 32-bit hash of the raw rdata
   1093 										// Note: This requirement is important. Various routines like AddAdditionalsToResponseList(),
   1094 										// ReconfirmAntecedents(), etc., use rdatahash as a pre-flight check to see
   1095 										// whether it's worth doing a full SameDomainName() call. If the rdatahash
   1096 										// is not a correct case-insensitive name hash, they'll get false negatives.
   1097 
   1098 	// Grouping pointers together at the end of the structure improves the memory layout efficiency
   1099 	mDNSInterfaceID  InterfaceID;		// Set if this RR is specific to one interface
   1100 										// For records received off the wire, InterfaceID is *always* set to the receiving interface
   1101 										// For our authoritative records, InterfaceID is usually zero, except for those few records
   1102 										// that are interface-specific (e.g. address records, especially linklocal addresses)
   1103 	const domainname *name;
   1104 	RData           *rdata;				// Pointer to storage for this rdata
   1105 	DNSServer       *rDNSServer;		// Unicast DNS server authoritative for this entry;null for multicast
   1106 	} ResourceRecord;
   1107 
   1108 // Unless otherwise noted, states may apply to either independent record registrations or service registrations
   1109 typedef enum
   1110 	{
   1111 	regState_Zero              = 0,
   1112 	regState_Pending           = 1,     // update sent, reply not received
   1113 	regState_Registered        = 2,     // update sent, reply received
   1114 	regState_DeregPending      = 3,     // dereg sent, reply not received
   1115 	regState_Unregistered      = 4,     // not in any list
   1116 	regState_Refresh           = 5,     // outstanding refresh (or target change) message
   1117 	regState_NATMap            = 6,     // establishing NAT port mapping
   1118 	regState_UpdatePending     = 7,     // update in flight as result of mDNS_Update call
   1119 	regState_NoTarget          = 8,     // SRV Record registration pending registration of hostname
   1120 	regState_NATError          = 9     // unable to complete NAT traversal
   1121 	} regState_t;
   1122 
   1123 enum
   1124 	{
   1125 	Target_Manual = 0,
   1126 	Target_AutoHost = 1,
   1127 	Target_AutoHostAndNATMAP = 2
   1128 	};
   1129 
   1130 typedef enum
   1131 	{
   1132 	mergeState_Zero = 0,
   1133 	mergeState_DontMerge = 1  // Set on fatal error conditions to disable merging
   1134 	} mergeState_t;
   1135 
   1136 struct AuthGroup_struct				// Header object for a list of AuthRecords with the same name
   1137 	{
   1138 	AuthGroup      *next;				// Next AuthGroup object in this hash table bucket
   1139 	mDNSu32         namehash;			// Name-based (i.e. case insensitive) hash of name
   1140 	AuthRecord     *members;			// List of CacheRecords with this same name
   1141 	AuthRecord    **rrauth_tail;		// Tail end of that list
   1142 	domainname     *name;				// Common name for all AuthRecords in this list
   1143 	AuthRecord     *NewLocalOnlyRecords;
   1144 	// Size to here is 20 bytes when compiling 32-bit; 40 bytes when compiling 64-bit
   1145 	mDNSu8          namestorage[InlineCacheGroupNameSize];
   1146 	};
   1147 
   1148 #define AUTH_HASH_SLOTS 499
   1149 #define FORALL_AUTHRECORDS(SLOT,AG,AR)                           	\
   1150 	for ((SLOT) = 0; (SLOT) < AUTH_HASH_SLOTS; (SLOT)++)         	\
   1151 		for ((AG)=m->rrauth.rrauth_hash[(SLOT)]; (AG); (AG)=(AG)->next) \
   1152 			for ((AR) = (AG)->members; (AR); (AR)=(AR)->next)
   1153 
   1154 typedef union AuthEntity_union AuthEntity;
   1155 union AuthEntity_union { AuthEntity *next; AuthGroup ag; };
   1156 typedef struct {
   1157 	mDNSu32 rrauth_size;				// Total number of available auth entries
   1158 	mDNSu32 rrauth_totalused;			// Number of auth entries currently occupied
   1159 	mDNSu32 rrauth_report;
   1160 	mDNSu8  rrauth_lock;				// For debugging: Set at times when these lists may not be modified
   1161 	AuthEntity *rrauth_free;
   1162 	AuthGroup *rrauth_hash[AUTH_HASH_SLOTS];
   1163 }AuthHash;
   1164 
   1165 // AuthRecordAny includes mDNSInterface_Any and interface specific auth records (anything
   1166 // other than P2P or LocalOnly)
   1167 typedef enum
   1168 	{
   1169 	AuthRecordAny, 				// registered for *Any, NOT including P2P interfaces
   1170 	AuthRecordAnyIncludeP2P, 	// registered for *Any, including P2P interfaces
   1171 	AuthRecordLocalOnly,
   1172 	AuthRecordP2P				// discovered over D2D/P2P framework
   1173 	} AuthRecType;
   1174 
   1175 struct AuthRecord_struct
   1176 	{
   1177 	// For examples of how to set up this structure for use in mDNS_Register(),
   1178 	// see mDNS_AdvertiseInterface() or mDNS_RegisterService().
   1179 	// Basically, resrec and persistent metadata need to be set up before calling mDNS_Register().
   1180 	// mDNS_SetupResourceRecord() is avaliable as a helper routine to set up most fields to sensible default values for you
   1181 
   1182 	AuthRecord     *next;				// Next in list; first element of structure for efficiency reasons
   1183 	// Field Group 1: Common ResourceRecord fields
   1184 	ResourceRecord  resrec;				// 36 bytes when compiling for 32-bit; 48 when compiling for 64-bit
   1185 
   1186 	// Field Group 2: Persistent metadata for Authoritative Records
   1187 	AuthRecord     *Additional1;		// Recommended additional record to include in response (e.g. SRV for PTR record)
   1188 	AuthRecord     *Additional2;		// Another additional (e.g. TXT for PTR record)
   1189 	AuthRecord     *DependentOn;		// This record depends on another for its uniqueness checking
   1190 	AuthRecord     *RRSet;				// This unique record is part of an RRSet
   1191 	mDNSRecordCallback *RecordCallback;	// Callback function to call for state changes, and to free memory asynchronously on deregistration
   1192 	void           *RecordContext;		// Context parameter for the callback function
   1193 	mDNSu8          AutoTarget;			// Set if the target of this record (PTR, CNAME, SRV, etc.) is our host name
   1194 	mDNSu8          AllowRemoteQuery;	// Set if we allow hosts not on the local link to query this record
   1195 	mDNSu8          ForceMCast;			// Set by client to advertise solely via multicast, even for apparently unicast names
   1196 
   1197 	OwnerOptData    WakeUp;				// WakeUp.HMAC.l[0] nonzero indicates that this is a Sleep Proxy record
   1198 	mDNSAddr        AddressProxy;		// For reverse-mapping Sleep Proxy PTR records, address in question
   1199 	mDNSs32         TimeRcvd;			// In platform time units
   1200 	mDNSs32         TimeExpire;			// In platform time units
   1201 	AuthRecType     ARType;             // LocalOnly, P2P or Normal ?
   1202 
   1203 	// Field Group 3: Transient state for Authoritative Records
   1204 	mDNSu8          Acknowledged;		// Set if we've given the success callback to the client
   1205 	mDNSu8          ProbeCount;			// Number of probes remaining before this record is valid (kDNSRecordTypeUnique)
   1206 	mDNSu8          AnnounceCount;		// Number of announcements remaining (kDNSRecordTypeShared)
   1207 	mDNSu8          RequireGoodbye;		// Set if this RR has been announced on the wire and will require a goodbye packet
   1208 	mDNSu8          AnsweredLocalQ;		// Set if this AuthRecord has been delivered to any local question (LocalOnly or mDNSInterface_Any)
   1209 	mDNSu8          IncludeInProbe;		// Set if this RR is being put into a probe right now
   1210 	mDNSu8          ImmedUnicast;		// Set if we may send our response directly via unicast to the requester
   1211 	mDNSInterfaceID SendNSECNow;		// Set if we need to generate associated NSEC data for this rrname
   1212 	mDNSInterfaceID ImmedAnswer;		// Someone on this interface issued a query we need to answer (all-ones for all interfaces)
   1213 #if MDNS_LOG_ANSWER_SUPPRESSION_TIMES
   1214 	mDNSs32         ImmedAnswerMarkTime;
   1215 #endif
   1216 	mDNSInterfaceID ImmedAdditional;	// Hint that we might want to also send this record, just to be helpful
   1217 	mDNSInterfaceID SendRNow;			// The interface this query is being sent on right now
   1218 	mDNSv4Addr      v4Requester;		// Recent v4 query for this record, or all-ones if more than one recent query
   1219 	mDNSv6Addr      v6Requester;		// Recent v6 query for this record, or all-ones if more than one recent query
   1220 	AuthRecord     *NextResponse;		// Link to the next element in the chain of responses to generate
   1221 	const mDNSu8   *NR_AnswerTo;		// Set if this record was selected by virtue of being a direct answer to a question
   1222 	AuthRecord     *NR_AdditionalTo;	// Set if this record was selected by virtue of being additional to another
   1223 	mDNSs32         ThisAPInterval;		// In platform time units: Current interval for announce/probe
   1224 	mDNSs32         LastAPTime;			// In platform time units: Last time we sent announcement/probe
   1225 	mDNSs32         LastMCTime;			// Last time we multicast this record (used to guard against packet-storm attacks)
   1226 	mDNSInterfaceID LastMCInterface;	// Interface this record was multicast on at the time LastMCTime was recorded
   1227 	RData          *NewRData;			// Set if we are updating this record with new rdata
   1228 	mDNSu16         newrdlength;		// ... and the length of the new RData
   1229 	mDNSRecordUpdateCallback *UpdateCallback;
   1230 	mDNSu32         UpdateCredits;		// Token-bucket rate limiting of excessive updates
   1231 	mDNSs32         NextUpdateCredit;	// Time next token is added to bucket
   1232 	mDNSs32         UpdateBlocked;		// Set if update delaying is in effect
   1233 
   1234 	// Field Group 4: Transient uDNS state for Authoritative Records
   1235 	regState_t   state;			// Maybe combine this with resrec.RecordType state? Right now it's ambiguous and confusing.
   1236 								// e.g. rr->resrec.RecordType can be kDNSRecordTypeUnregistered,
   1237 								// and rr->state can be regState_Unregistered
   1238 								// What if we find one of those statements is true and the other false? What does that mean?
   1239 	mDNSBool     uselease;		// dynamic update contains (should contain) lease option
   1240 	mDNSs32      expire;		// In platform time units: expiration of lease (-1 for static)
   1241 	mDNSBool     Private;		// If zone is private, DNS updates may have to be encrypted to prevent eavesdropping
   1242 	mDNSOpaque16 updateid;		// Identifier to match update request and response -- also used when transferring records to Sleep Proxy
   1243 	const domainname *zone;		// the zone that is updated
   1244 	ZoneData  *nta;
   1245 	struct tcpInfo_t *tcp;
   1246 	NATTraversalInfo  NATinfo;
   1247 	mDNSBool SRVChanged;       // temporarily deregistered service because its SRV target or port changed
   1248 	mergeState_t  mState;      // Unicast Record Registrations merge state
   1249 	mDNSu8		  refreshCount; // Number of refreshes to the server
   1250 	mStatus		  updateError;  // Record update resulted in Error ?
   1251 
   1252 	// uDNS_UpdateRecord support fields
   1253 	// Do we really need all these in *addition* to NewRData and newrdlength above?
   1254 	void *UpdateContext;	// Context parameter for the update callback function
   1255 	mDNSu16 OrigRDLen;		// previously registered, being deleted
   1256 	mDNSu16 InFlightRDLen;	// currently being registered
   1257 	mDNSu16 QueuedRDLen;	// pending operation (re-transmitting if necessary) THEN register the queued update
   1258 	RData *OrigRData;
   1259 	RData *InFlightRData;
   1260 	RData *QueuedRData;
   1261 
   1262 	// Field Group 5: Large data objects go at the end
   1263 	domainname      namestorage;
   1264 	RData           rdatastorage;		// Normally the storage is right here, except for oversized records
   1265 	// rdatastorage MUST be the last thing in the structure -- when using oversized AuthRecords, extra bytes
   1266 	// are appended after the end of the AuthRecord, logically augmenting the size of the rdatastorage
   1267 	// DO NOT ADD ANY MORE FIELDS HERE
   1268 	};
   1269 
   1270 // IsLocalDomain alone is not sufficient to determine that a record is mDNS or uDNS. By default domain names within
   1271 // the "local" pseudo-TLD (and within the IPv4 and IPv6 link-local reverse mapping domains) are automatically treated
   1272 // as mDNS records, but it is also possible to force any record (even those not within one of the inherently local
   1273 // domains) to be handled as an mDNS record by setting the ForceMCast flag, or by setting a non-zero InterfaceID.
   1274 // For example, the reverse-mapping PTR record created in AdvertiseInterface sets the ForceMCast flag, since it points to
   1275 // a dot-local hostname, and therefore it would make no sense to register this record with a wide-area Unicast DNS server.
   1276 // The same applies to Sleep Proxy records, which we will answer for when queried via mDNS, but we never want to try
   1277 // to register them with a wide-area Unicast DNS server -- and we probably don't have the required credentials anyway.
   1278 // Currently we have no concept of a wide-area uDNS record scoped to a particular interface, so if the InterfaceID is
   1279 // nonzero we treat this the same as ForceMCast.
   1280 // Note: Question_uDNS(Q) is used in *only* one place -- on entry to mDNS_StartQuery_internal, to decide whether to set TargetQID.
   1281 // Everywhere else in the code, the determination of whether a question is unicast is made by checking to see if TargetQID is nonzero.
   1282 #define AuthRecord_uDNS(R) ((R)->resrec.InterfaceID == mDNSInterface_Any && !(R)->ForceMCast && !IsLocalDomain((R)->resrec.name))
   1283 #define Question_uDNS(Q)   ((Q)->InterfaceID == mDNSInterface_Unicast || \
   1284 	((Q)->InterfaceID != mDNSInterface_LocalOnly && (Q)->InterfaceID != mDNSInterface_P2P && !(Q)->ForceMCast && !IsLocalDomain(&(Q)->qname)))
   1285 
   1286 #define RRLocalOnly(rr) ((rr)->ARType == AuthRecordLocalOnly || (rr)->ARType == AuthRecordP2P)
   1287 
   1288 #define RRAny(rr) ((rr)->ARType == AuthRecordAny || (rr)->ARType == AuthRecordAnyIncludeP2P)
   1289 
   1290 // Question (A or AAAA) that is suppressed currently because IPv4 or IPv6 address
   1291 // is not available locally for A or AAAA question respectively
   1292 #define QuerySuppressed(Q) ((Q)->SuppressUnusable && (Q)->SuppressQuery)
   1293 
   1294 #define PrivateQuery(Q) ((Q)->AuthInfo && (Q)->AuthInfo->AutoTunnel)
   1295 
   1296 // Normally we always lookup the cache and /etc/hosts before sending the query on the wire. For single label
   1297 // queries (A and AAAA) that are unqualified (indicated by AppendSearchDomains), we want to append search
   1298 // domains before we try them as such
   1299 #define ApplySearchDomainsFirst(q) ((q)->AppendSearchDomains && (CountLabels(&((q)->qname))) == 1)
   1300 
   1301 // Wrapper struct for Auth Records for higher-level code that cannot use the AuthRecord's ->next pointer field
   1302 typedef struct ARListElem
   1303 	{
   1304 	struct ARListElem *next;
   1305 	AuthRecord ar;          // Note: Must be last element of structure, to accomodate oversized AuthRecords
   1306 	} ARListElem;
   1307 
   1308 struct CacheGroup_struct				// Header object for a list of CacheRecords with the same name
   1309 	{
   1310 	CacheGroup     *next;				// Next CacheGroup object in this hash table bucket
   1311 	mDNSu32         namehash;			// Name-based (i.e. case insensitive) hash of name
   1312 	CacheRecord    *members;			// List of CacheRecords with this same name
   1313 	CacheRecord   **rrcache_tail;		// Tail end of that list
   1314 	domainname     *name;				// Common name for all CacheRecords in this list
   1315 	// Size to here is 20 bytes when compiling 32-bit; 40 bytes when compiling 64-bit
   1316 	mDNSu8          namestorage[InlineCacheGroupNameSize];
   1317 	};
   1318 
   1319 
   1320 struct CacheRecord_struct
   1321 	{
   1322 	CacheRecord    *next;				// Next in list; first element of structure for efficiency reasons
   1323 	ResourceRecord  resrec;				// 36 bytes when compiling for 32-bit; 48 when compiling for 64-bit
   1324 
   1325 	// Transient state for Cache Records
   1326 	CacheRecord    *NextInKAList;		// Link to the next element in the chain of known answers to send
   1327 	mDNSs32         TimeRcvd;			// In platform time units
   1328 	mDNSs32         DelayDelivery;		// Set if we want to defer delivery of this answer to local clients
   1329 	mDNSs32         NextRequiredQuery;	// In platform time units
   1330 	mDNSs32         LastUsed;			// In platform time units
   1331 	DNSQuestion    *CRActiveQuestion;	// Points to an active question referencing this answer. Can never point to a NewQuestion.
   1332 	mDNSu32         UnansweredQueries;	// Number of times we've issued a query for this record without getting an answer
   1333 	mDNSs32         LastUnansweredTime;	// In platform time units; last time we incremented UnansweredQueries
   1334 #if ENABLE_MULTI_PACKET_QUERY_SNOOPING
   1335 	mDNSu32         MPUnansweredQ;		// Multi-packet query handling: Number of times we've seen a query for this record
   1336 	mDNSs32         MPLastUnansweredQT;	// Multi-packet query handling: Last time we incremented MPUnansweredQ
   1337 	mDNSu32         MPUnansweredKA;		// Multi-packet query handling: Number of times we've seen this record in a KA list
   1338 	mDNSBool        MPExpectingKA;		// Multi-packet query handling: Set when we increment MPUnansweredQ; allows one KA
   1339 #endif
   1340 	CacheRecord    *NextInCFList;		// Set if this is in the list of records we just received with the cache flush bit set
   1341 	// Size to here is 76 bytes when compiling 32-bit; 104 bytes when compiling 64-bit
   1342 	RData_small     smallrdatastorage;	// Storage for small records is right here (4 bytes header + 68 bytes data = 72 bytes)
   1343 	};
   1344 
   1345 // Storage sufficient to hold either a CacheGroup header or a CacheRecord
   1346 // -- for best efficiency (to avoid wasted unused storage) they should be the same size
   1347 typedef union CacheEntity_union CacheEntity;
   1348 union CacheEntity_union { CacheEntity *next; CacheGroup cg; CacheRecord cr; };
   1349 
   1350 typedef struct
   1351 	{
   1352 	CacheRecord r;
   1353 	mDNSu8 _extradata[MaximumRDSize-InlineCacheRDSize];		// Glue on the necessary number of extra bytes
   1354 	domainname namestorage;									// Needs to go *after* the extra rdata bytes
   1355 	} LargeCacheRecord;
   1356 
   1357 typedef struct HostnameInfo
   1358 	{
   1359 	struct HostnameInfo *next;
   1360 	NATTraversalInfo natinfo;
   1361 	domainname fqdn;
   1362 	AuthRecord arv4;                          // registered IPv4 address record
   1363 	AuthRecord arv6;                          // registered IPv6 address record
   1364 	mDNSRecordCallback *StatusCallback;       // callback to deliver success or error code to client layer
   1365 	const void *StatusContext;                // Client Context
   1366 	} HostnameInfo;
   1367 
   1368 typedef struct ExtraResourceRecord_struct ExtraResourceRecord;
   1369 struct ExtraResourceRecord_struct
   1370 	{
   1371 	ExtraResourceRecord *next;
   1372 	mDNSu32 ClientID;  // Opaque ID field to be used by client to map an AddRecord call to a set of Extra records
   1373 	AuthRecord r;
   1374 	// Note: Add any additional fields *before* the AuthRecord in this structure, not at the end.
   1375 	// In some cases clients can allocate larger chunks of memory and set r->rdata->MaxRDLength to indicate
   1376 	// that this extra memory is available, which would result in any fields after the AuthRecord getting smashed
   1377 	};
   1378 
   1379 // Note: Within an mDNSServiceCallback mDNS all API calls are legal except mDNS_Init(), mDNS_Exit(), mDNS_Execute()
   1380 typedef void mDNSServiceCallback(mDNS *const m, ServiceRecordSet *const sr, mStatus result);
   1381 
   1382 // A ServiceRecordSet has no special meaning to the core code of the Multicast DNS protocol engine;
   1383 // it is just a convenience structure to group together the records that make up a standard service
   1384 // registration so that they can be allocted and deallocted together as a single memory object.
   1385 // It contains its own ServiceCallback+ServiceContext to report aggregate results up to the next layer of software above.
   1386 // It also contains:
   1387 //  * the basic PTR/SRV/TXT triplet used to represent any DNS-SD service
   1388 //  * the "_services" PTR record for service enumeration
   1389 //  * the optional list of SubType PTR records
   1390 //  * the optional list of additional records attached to the service set (e.g. iChat pictures)
   1391 
   1392 struct ServiceRecordSet_struct
   1393 	{
   1394 	// These internal state fields are used internally by mDNSCore; the client layer needn't be concerned with them.
   1395 	// No fields need to be set up by the client prior to calling mDNS_RegisterService();
   1396 	// all required data is passed as parameters to that function.
   1397 	mDNSServiceCallback *ServiceCallback;
   1398 	void                *ServiceContext;
   1399 	mDNSBool             Conflict;	// Set if this record set was forcibly deregistered because of a conflict
   1400 
   1401 	ExtraResourceRecord *Extras;	// Optional list of extra AuthRecords attached to this service registration
   1402 	mDNSu32              NumSubTypes;
   1403 	AuthRecord          *SubTypes;
   1404 	AuthRecord           RR_ADV;	// e.g. _services._dns-sd._udp.local. PTR _printer._tcp.local.
   1405 	AuthRecord           RR_PTR;	// e.g. _printer._tcp.local.        PTR Name._printer._tcp.local.
   1406 	AuthRecord           RR_SRV;	// e.g. Name._printer._tcp.local.   SRV 0 0 port target
   1407 	AuthRecord           RR_TXT;	// e.g. Name._printer._tcp.local.   TXT PrintQueueName
   1408 	// Don't add any fields after AuthRecord RR_TXT.
   1409 	// This is where the implicit extra space goes if we allocate a ServiceRecordSet containing an oversized RR_TXT record
   1410 	};
   1411 
   1412 // ***************************************************************************
   1413 #if 0
   1414 #pragma mark -
   1415 #pragma mark - Question structures
   1416 #endif
   1417 
   1418 // We record the last eight instances of each duplicate query
   1419 // This gives us v4/v6 on each of Ethernet, AirPort and Firewire, and two free slots "for future expansion"
   1420 // If the host has more active interfaces that this it is not fatal -- duplicate question suppression will degrade gracefully.
   1421 // Since we will still remember the last eight, the busiest interfaces will still get the effective duplicate question suppression.
   1422 #define DupSuppressInfoSize 8
   1423 
   1424 typedef struct
   1425 	{
   1426 	mDNSs32               Time;
   1427 	mDNSInterfaceID       InterfaceID;
   1428 	mDNSs32               Type;				// v4 or v6?
   1429 	} DupSuppressInfo;
   1430 
   1431 typedef enum
   1432 	{
   1433 	LLQ_InitialRequest    = 1,
   1434 	LLQ_SecondaryRequest  = 2,
   1435 	LLQ_Established       = 3,
   1436 	LLQ_Poll              = 4
   1437 	} LLQ_State;
   1438 
   1439 // LLQ constants
   1440 #define kLLQ_Vers      1
   1441 #define kLLQ_DefLease  7200 // 2 hours
   1442 #define kLLQ_MAX_TRIES 3    // retry an operation 3 times max
   1443 #define kLLQ_INIT_RESEND 2 // resend an un-ack'd packet after 2 seconds, then double for each additional
   1444 // LLQ Operation Codes
   1445 #define kLLQOp_Setup     1
   1446 #define kLLQOp_Refresh   2
   1447 #define kLLQOp_Event     3
   1448 
   1449 // LLQ Errror Codes
   1450 enum
   1451 	{
   1452 	LLQErr_NoError    = 0,
   1453 	LLQErr_ServFull   = 1,
   1454 	LLQErr_Static     = 2,
   1455 	LLQErr_FormErr    = 3,
   1456 	LLQErr_NoSuchLLQ  = 4,
   1457 	LLQErr_BadVers    = 5,
   1458 	LLQErr_UnknownErr = 6
   1459 	};
   1460 
   1461 enum { NoAnswer_Normal = 0, NoAnswer_Suspended = 1, NoAnswer_Fail = 2 };
   1462 
   1463 #define HMAC_LEN    64
   1464 #define HMAC_IPAD   0x36
   1465 #define HMAC_OPAD   0x5c
   1466 #define MD5_LEN     16
   1467 
   1468 #define AutoTunnelUnregistered(X) (                                              \
   1469 	(X)->AutoTunnelHostRecord.resrec.RecordType == kDNSRecordTypeUnregistered && \
   1470 	(X)->AutoTunnelDeviceInfo.resrec.RecordType == kDNSRecordTypeUnregistered && \
   1471 	(X)->AutoTunnelService.   resrec.RecordType == kDNSRecordTypeUnregistered && \
   1472 	(X)->AutoTunnel6Record.   resrec.RecordType == kDNSRecordTypeUnregistered    )
   1473 
   1474 // Internal data structure to maintain authentication information
   1475 typedef struct DomainAuthInfo
   1476 	{
   1477 	struct DomainAuthInfo *next;
   1478 	mDNSs32          deltime;				// If we're planning to delete this DomainAuthInfo, the time we want it deleted
   1479 	const char*      AutoTunnel;            // If NULL, this is not an AutoTunnel DAI. Otherwise, this is prepended to the IPSec identifier
   1480 	AuthRecord       AutoTunnelHostRecord;	// User-visible hostname; used as SRV target for AutoTunnel services
   1481 	AuthRecord       AutoTunnelTarget;		// Opaque hostname of tunnel endpoint; used as SRV target for AutoTunnelService record
   1482 	AuthRecord       AutoTunnelDeviceInfo;	// Device info of tunnel endpoint
   1483 	AuthRecord       AutoTunnelService;		// Service record (possibly NAT-Mapped) of IKE daemon implementing tunnel endpoint
   1484 	AuthRecord       AutoTunnel6Record;     // AutoTunnel AAAA Record obtained from Connectivityd
   1485 	NATTraversalInfo AutoTunnelNAT;
   1486 	domainname       domain;
   1487 	domainname       keyname;
   1488 	domainname       hostname;
   1489 	mDNSIPPort       port;
   1490 	char             b64keydata[32];
   1491 	mDNSu8           keydata_ipad[HMAC_LEN];	// padded key for inner hash rounds
   1492 	mDNSu8           keydata_opad[HMAC_LEN];	// padded key for outer hash rounds
   1493 	} DomainAuthInfo;
   1494 
   1495 // Note: Within an mDNSQuestionCallback mDNS all API calls are legal except mDNS_Init(), mDNS_Exit(), mDNS_Execute()
   1496 typedef enum { QC_rmv = 0, QC_add = 1, QC_addnocache = 2 } QC_result;
   1497 typedef void mDNSQuestionCallback(mDNS *const m, DNSQuestion *question, const ResourceRecord *const answer, QC_result AddRecord);
   1498 
   1499 #define NextQSendTime(Q)  ((Q)->LastQTime + (Q)->ThisQInterval)
   1500 #define ActiveQuestion(Q) ((Q)->ThisQInterval > 0 && !(Q)->DuplicateOf)
   1501 #define TimeToSendThisQuestion(Q,time) (ActiveQuestion(Q) && (time) - NextQSendTime(Q) >= 0)
   1502 
   1503 struct DNSQuestion_struct
   1504 	{
   1505 	// Internal state fields. These are used internally by mDNSCore; the client layer needn't be concerned with them.
   1506 	DNSQuestion          *next;
   1507 	mDNSu32               qnamehash;
   1508 	mDNSs32               DelayAnswering;	// Set if we want to defer answering this question until the cache settles
   1509 	mDNSs32               LastQTime;		// Last scheduled transmission of this Q on *all* applicable interfaces
   1510 	mDNSs32               ThisQInterval;	// LastQTime + ThisQInterval is the next scheduled transmission of this Q
   1511 											// ThisQInterval > 0 for an active question;
   1512 											// ThisQInterval = 0 for a suspended question that's still in the list
   1513 											// ThisQInterval = -1 for a cancelled question (should not still be in list)
   1514 	mDNSs32               ExpectUnicastResp;// Set when we send a query with the kDNSQClass_UnicastResponse bit set
   1515 	mDNSs32               LastAnswerPktNum;	// The sequence number of the last response packet containing an answer to this Q
   1516 	mDNSu32               RecentAnswerPkts;	// Number of answers since the last time we sent this query
   1517 	mDNSu32               CurrentAnswers;	// Number of records currently in the cache that answer this question
   1518 	mDNSu32               LargeAnswers;		// Number of answers with rdata > 1024 bytes
   1519 	mDNSu32               UniqueAnswers;	// Number of answers received with kDNSClass_UniqueRRSet bit set
   1520 	mDNSInterfaceID       FlappingInterface1;// Set when an interface goes away, to flag if remove events are delivered for this Q
   1521 	mDNSInterfaceID       FlappingInterface2;// Set when an interface goes away, to flag if remove events are delivered for this Q
   1522 	DomainAuthInfo       *AuthInfo;			// Non-NULL if query is currently being done using Private DNS
   1523 	DNSQuestion          *DuplicateOf;
   1524 	DNSQuestion          *NextInDQList;
   1525 	DupSuppressInfo       DupSuppress[DupSuppressInfoSize];
   1526 	mDNSInterfaceID       SendQNow;			// The interface this query is being sent on right now
   1527 	mDNSBool              SendOnAll;		// Set if we're sending this question on all active interfaces
   1528 	mDNSu32               RequestUnicast;	// Non-zero if we want to send query with kDNSQClass_UnicastResponse bit set
   1529 	mDNSs32               LastQTxTime;		// Last time this Q was sent on one (but not necessarily all) interfaces
   1530 	mDNSu32               CNAMEReferrals;	// Count of how many CNAME redirections we've done
   1531 	mDNSBool              SuppressQuery;    // This query should be suppressed and not sent on the wire
   1532 	mDNSu8                LOAddressAnswers; // Number of answers from the local only auth records that are
   1533 		                                    // answering A, AAAA and CNAME (/etc/hosts)
   1534 	mDNSu8                WakeOnResolveCount; // Number of wakes that should be sent on resolve
   1535 	mDNSs32               StopTime;			// Time this question should be stopped by giving them a negative answer
   1536 
   1537 	// Wide Area fields. These are used internally by the uDNS core
   1538 	UDPSocket            *LocalSocket;
   1539 	mDNSBool             deliverAddEvents;  // Change in DNSSserver requiring to deliver ADD events
   1540 	DNSServer            *qDNSServer;		// Caching server for this query (in the absence of an SRV saying otherwise)
   1541 	mDNSOpaque64          validDNSServers;  // Valid DNSServers for this question
   1542 	mDNSu16              noServerResponse;  // At least one server did not respond.
   1543 	mDNSu16              triedAllServersOnce; // Tried all DNS servers once
   1544 	mDNSu8               unansweredQueries;// The number of unanswered queries to this server
   1545 
   1546 	ZoneData             *nta;				// Used for getting zone data for private or LLQ query
   1547 	mDNSAddr              servAddr;			// Address and port learned from _dns-llq, _dns-llq-tls or _dns-query-tls SRV query
   1548 	mDNSIPPort            servPort;
   1549 	struct tcpInfo_t *tcp;
   1550 	mDNSIPPort            tcpSrcPort;		// Local Port TCP packet received on;need this as tcp struct is disposed
   1551 											// by tcpCallback before calling into mDNSCoreReceive
   1552 	mDNSu8                NoAnswer;			// Set if we want to suppress answers until tunnel setup has completed
   1553 
   1554 	// LLQ-specific fields. These fields are only meaningful when LongLived flag is set
   1555 	LLQ_State             state;
   1556 	mDNSu32               ReqLease;			// seconds (relative)
   1557 	mDNSs32               expire;			// ticks (absolute)
   1558 	mDNSs16               ntries;           // for UDP: the number of packets sent for this LLQ state
   1559 	                                       // for TCP: there is some ambiguity in the use of this variable, but in general, it is
   1560 	                                       //          the number of TCP/TLS connection attempts for this LLQ state, or
   1561 	                                       //          the number of packets sent for this TCP/TLS connection
   1562 	mDNSOpaque64          id;
   1563 
   1564 	// Client API fields: The client must set up these fields *before* calling mDNS_StartQuery()
   1565 	mDNSInterfaceID       InterfaceID;		// Non-zero if you want to issue queries only on a single specific IP interface
   1566 	mDNSAddr              Target;			// Non-zero if you want to direct queries to a specific unicast target address
   1567 	mDNSIPPort            TargetPort;		// Must be set if Target is set
   1568 	mDNSOpaque16          TargetQID;		// Must be set if Target is set
   1569 	domainname            qname;
   1570 	mDNSu16               qtype;
   1571 	mDNSu16               qclass;
   1572 	mDNSBool              LongLived;        // Set by client for calls to mDNS_StartQuery to indicate LLQs to unicast layer.
   1573 	mDNSBool              ExpectUnique;		// Set by client if it's expecting unique RR(s) for this question, not shared RRs
   1574 	mDNSBool              ForceMCast;		// Set by client to force mDNS query, even for apparently uDNS names
   1575 	mDNSBool              ReturnIntermed;	// Set by client to request callbacks for intermediate CNAME/NXDOMAIN results
   1576 	mDNSBool              SuppressUnusable; // Set by client to suppress unusable queries to be sent on the wire
   1577 	mDNSBool              RetryWithSearchDomains;	// Retry with search domains if there is no entry in the cache or AuthRecords
   1578 	mDNSu8                TimeoutQuestion; // Timeout this question if there is no reply in configured time
   1579 	mDNSu8                WakeOnResolve; // Send wakeup on resolve
   1580 	mDNSs8                SearchListIndex;  // Index into SearchList; Used by the client layer but not touched by core
   1581 	mDNSs8                AppendSearchDomains; // Search domains can be appended for this query
   1582 	mDNSs8                AppendLocalSearchDomains; // Search domains ending in .local can be appended for this query
   1583 	domainname           *qnameOrig;       // Copy of the original question name if it is not fully qualified
   1584 	mDNSQuestionCallback *QuestionCallback;
   1585 	void                 *QuestionContext;
   1586 	};
   1587 
   1588 typedef struct
   1589 	{
   1590 	// Client API fields: The client must set up name and InterfaceID *before* calling mDNS_StartResolveService()
   1591 	// When the callback is invoked, ip, port, TXTlen and TXTinfo will have been filled in with the results learned from the network.
   1592 	domainname      name;
   1593 	mDNSInterfaceID InterfaceID;		// ID of the interface the response was received on
   1594 	mDNSAddr        ip;					// Remote (destination) IP address where this service can be accessed
   1595 	mDNSIPPort      port;				// Port where this service can be accessed
   1596 	mDNSu16         TXTlen;
   1597 	mDNSu8          TXTinfo[2048];		// Additional demultiplexing information (e.g. LPR queue name)
   1598 	} ServiceInfo;
   1599 
   1600 // Note: Within an mDNSServiceInfoQueryCallback mDNS all API calls are legal except mDNS_Init(), mDNS_Exit(), mDNS_Execute()
   1601 typedef struct ServiceInfoQuery_struct ServiceInfoQuery;
   1602 typedef void mDNSServiceInfoQueryCallback(mDNS *const m, ServiceInfoQuery *query);
   1603 struct ServiceInfoQuery_struct
   1604 	{
   1605 	// Internal state fields. These are used internally by mDNSCore; the client layer needn't be concerned with them.
   1606 	// No fields need to be set up by the client prior to calling mDNS_StartResolveService();
   1607 	// all required data is passed as parameters to that function.
   1608 	// The ServiceInfoQuery structure memory is working storage for mDNSCore to discover the requested information
   1609 	// and place it in the ServiceInfo structure. After the client has called mDNS_StopResolveService(), it may
   1610 	// dispose of the ServiceInfoQuery structure while retaining the results in the ServiceInfo structure.
   1611 	DNSQuestion                   qSRV;
   1612 	DNSQuestion                   qTXT;
   1613 	DNSQuestion                   qAv4;
   1614 	DNSQuestion                   qAv6;
   1615 	mDNSu8                        GotSRV;
   1616 	mDNSu8                        GotTXT;
   1617 	mDNSu8                        GotADD;
   1618 	mDNSu32                       Answers;
   1619 	ServiceInfo                  *info;
   1620 	mDNSServiceInfoQueryCallback *ServiceInfoQueryCallback;
   1621 	void                         *ServiceInfoQueryContext;
   1622 	};
   1623 
   1624 typedef enum { ZoneServiceUpdate, ZoneServiceQuery, ZoneServiceLLQ } ZoneService;
   1625 
   1626 typedef void ZoneDataCallback(mDNS *const m, mStatus err, const ZoneData *result);
   1627 
   1628 struct ZoneData_struct
   1629 	{
   1630 	domainname       ChildName;			// Name for which we're trying to find the responsible server
   1631 	ZoneService      ZoneService;		// Which service we're seeking for this zone (update, query, or LLQ)
   1632 	domainname       *CurrentSOA;		// Points to somewhere within ChildName
   1633 	domainname       ZoneName;			// Discovered result: Left-hand-side of SOA record
   1634 	mDNSu16          ZoneClass;			// Discovered result: DNS Class from SOA record
   1635 	domainname       Host;				// Discovered result: Target host from SRV record
   1636 	mDNSIPPort       Port;				// Discovered result: Update port, query port, or LLQ port from SRV record
   1637 	mDNSAddr         Addr;				// Discovered result: Address of Target host from SRV record
   1638 	mDNSBool         ZonePrivate;		// Discovered result: Does zone require encrypted queries?
   1639 	ZoneDataCallback *ZoneDataCallback;	// Caller-specified function to be called upon completion
   1640 	void             *ZoneDataContext;
   1641 	DNSQuestion      question;			// Storage for any active question
   1642 	};
   1643 
   1644 extern ZoneData *StartGetZoneData(mDNS *const m, const domainname *const name, const ZoneService target, ZoneDataCallback callback, void *callbackInfo);
   1645 extern void CancelGetZoneData(mDNS *const m, ZoneData *nta);
   1646 extern mDNSBool IsGetZoneDataQuestion(DNSQuestion *q);
   1647 
   1648 typedef struct DNameListElem
   1649 	{
   1650 	struct DNameListElem *next;
   1651 	mDNSu32 uid;
   1652 	domainname name;
   1653 	} DNameListElem;
   1654 
   1655 #if APPLE_OSX_mDNSResponder
   1656 // Different states that we go through locating the peer
   1657 #define TC_STATE_AAAA_PEER			0x000000001		/* Peer's BTMM IPv6 address */
   1658 #define TC_STATE_AAAA_PEER_RELAY	0x000000002		/* Peer's IPv6 Relay address */
   1659 #define TC_STATE_SRV_PEER			0x000000003		/* Peer's SRV Record corresponding to IPv4 address */
   1660 #define TC_STATE_ADDR_PEER			0x000000004		/* Peer's IPv4 address */
   1661 
   1662 typedef struct ClientTunnel
   1663 	{
   1664 	struct ClientTunnel *next;
   1665 	const char *prefix;
   1666 	domainname dstname;
   1667 	mDNSBool   MarkedForDeletion;
   1668 	mDNSv6Addr loc_inner;
   1669 	mDNSv4Addr loc_outer;
   1670 	mDNSv6Addr loc_outer6;
   1671 	mDNSv6Addr rmt_inner;
   1672 	mDNSv4Addr rmt_outer;
   1673 	mDNSv6Addr rmt_outer6;
   1674 	mDNSIPPort rmt_outer_port;
   1675 	mDNSu16	tc_state;
   1676 	DNSQuestion q;
   1677 	} ClientTunnel;
   1678 #endif
   1679 
   1680 // ***************************************************************************
   1681 #if 0
   1682 #pragma mark -
   1683 #pragma mark - NetworkInterfaceInfo_struct
   1684 #endif
   1685 
   1686 typedef struct NetworkInterfaceInfo_struct NetworkInterfaceInfo;
   1687 
   1688 // A NetworkInterfaceInfo_struct serves two purposes:
   1689 // 1. It holds the address, PTR and HINFO records to advertise a given IP address on a given physical interface
   1690 // 2. It tells mDNSCore which physical interfaces are available; each physical interface has its own unique InterfaceID.
   1691 //    Since there may be multiple IP addresses on a single physical interface,
   1692 //    there may be multiple NetworkInterfaceInfo_structs with the same InterfaceID.
   1693 //    In this case, to avoid sending the same packet n times, when there's more than one
   1694 //    struct with the same InterfaceID, mDNSCore picks one member of the set to be the
   1695 //    active representative of the set; all others have the 'InterfaceActive' flag unset.
   1696 
   1697 struct NetworkInterfaceInfo_struct
   1698 	{
   1699 	// Internal state fields. These are used internally by mDNSCore; the client layer needn't be concerned with them.
   1700 	NetworkInterfaceInfo *next;
   1701 
   1702 	mDNSu8          InterfaceActive;	// Set if interface is sending & receiving packets (see comment above)
   1703 	mDNSu8          IPv4Available;		// If InterfaceActive, set if v4 available on this InterfaceID
   1704 	mDNSu8          IPv6Available;		// If InterfaceActive, set if v6 available on this InterfaceID
   1705 
   1706 	DNSQuestion     NetWakeBrowse;
   1707 	DNSQuestion     NetWakeResolve[3];	// For fault-tolerance, we try up to three Sleep Proxies
   1708 	mDNSAddr        SPSAddr[3];
   1709 	mDNSIPPort      SPSPort[3];
   1710 	mDNSs32         NextSPSAttempt;		// -1 if we're not currently attempting to register with any Sleep Proxy
   1711 	mDNSs32         NextSPSAttemptTime;
   1712 
   1713 	// Standard AuthRecords that every Responder host should have (one per active IP address)
   1714 	AuthRecord RR_A;					// 'A' or 'AAAA' (address) record for our ".local" name
   1715 	AuthRecord RR_PTR;					// PTR (reverse lookup) record
   1716 	AuthRecord RR_HINFO;
   1717 
   1718 	// Client API fields: The client must set up these fields *before* calling mDNS_RegisterInterface()
   1719 	mDNSInterfaceID InterfaceID;		// Identifies physical interface; MUST NOT be 0, -1, or -2
   1720 	mDNSAddr        ip;					// The IPv4 or IPv6 address to advertise
   1721 	mDNSAddr        mask;
   1722 	mDNSEthAddr     MAC;
   1723 	char            ifname[64];			// Windows uses a GUID string for the interface name, which doesn't fit in 16 bytes
   1724 	mDNSu8          Advertise;			// False if you are only searching on this interface
   1725 	mDNSu8          McastTxRx;			// Send/Receive multicast on this { InterfaceID, address family } ?
   1726 	mDNSu8          NetWake;			// Set if Wake-On-Magic-Packet is enabled on this interface
   1727 	mDNSu8          Loopback;			// Set if this is the loopback interface
   1728 	};
   1729 
   1730 #define SLE_DELETE              0x00000001
   1731 #define SLE_WAB_QUERY_STARTED   0x00000002
   1732 
   1733 typedef struct SearchListElem
   1734 	{
   1735 	struct SearchListElem *next;
   1736 	domainname domain;
   1737 	int flag;
   1738 	mDNSInterfaceID InterfaceID;
   1739 	DNSQuestion BrowseQ;
   1740 	DNSQuestion DefBrowseQ;
   1741 	DNSQuestion AutomaticBrowseQ;
   1742 	DNSQuestion RegisterQ;
   1743 	DNSQuestion DefRegisterQ;
   1744 	int	numCfAnswers;
   1745 	ARListElem *AuthRecs;
   1746 	} SearchListElem;
   1747 
   1748 // For domain enumeration and automatic browsing
   1749 // This is the user's DNS search list.
   1750 // In each of these domains we search for our special pointer records (lb._dns-sd._udp.<domain>, etc.)
   1751 // to discover recommended domains for domain enumeration (browse, default browse, registration,
   1752 // default registration) and possibly one or more recommended automatic browsing domains.
   1753 extern SearchListElem *SearchList;		// This really ought to be part of mDNS_struct -- SC
   1754 
   1755 // ***************************************************************************
   1756 #if 0
   1757 #pragma mark -
   1758 #pragma mark - Main mDNS object, used to hold all the mDNS state
   1759 #endif
   1760 
   1761 typedef void mDNSCallback(mDNS *const m, mStatus result);
   1762 
   1763 #define CACHE_HASH_SLOTS 499
   1764 
   1765 enum		// Bit flags -- i.e. values should be 1, 2, 4, 8, etc.
   1766 	{
   1767 	mDNS_KnownBug_LimitedIPv6       = 1,
   1768 	mDNS_KnownBug_LossySyslog       = 2		// <rdar://problem/6561888>
   1769 	};
   1770 
   1771 enum
   1772 	{
   1773 	SleepState_Awake = 0,
   1774 	SleepState_Transferring = 1,
   1775 	SleepState_Sleeping = 2
   1776 	};
   1777 
   1778 struct mDNS_struct
   1779 	{
   1780 	// Internal state fields. These hold the main internal state of mDNSCore;
   1781 	// the client layer needn't be concerned with them.
   1782 	// No fields need to be set up by the client prior to calling mDNS_Init();
   1783 	// all required data is passed as parameters to that function.
   1784 
   1785 	mDNS_PlatformSupport *p;			// Pointer to platform-specific data of indeterminite size
   1786 	mDNSu32  KnownBugs;
   1787 	mDNSBool CanReceiveUnicastOn5353;
   1788 	mDNSBool AdvertiseLocalAddresses;
   1789 	mDNSBool DivertMulticastAdvertisements; // from interfaces that do not advertise local addresses to local-only
   1790 	mStatus mDNSPlatformStatus;
   1791 	mDNSIPPort UnicastPort4;
   1792 	mDNSIPPort UnicastPort6;
   1793 	mDNSEthAddr PrimaryMAC;				// Used as unique host ID
   1794 	mDNSCallback *MainCallback;
   1795 	void         *MainContext;
   1796 
   1797 	// For debugging: To catch and report locking failures
   1798 	mDNSu32 mDNS_busy;					// Incremented between mDNS_Lock/mDNS_Unlock section
   1799 	mDNSu32 mDNS_reentrancy;			// Incremented when calling a client callback
   1800 	mDNSu8  lock_rrcache;				// For debugging: Set at times when these lists may not be modified
   1801 	mDNSu8  lock_Questions;
   1802 	mDNSu8  lock_Records;
   1803 #ifndef MaxMsg
   1804 	#define MaxMsg 160
   1805 #endif
   1806 	char MsgBuffer[MaxMsg];				// Temp storage used while building error log messages
   1807 
   1808 	// Task Scheduling variables
   1809 	mDNSs32  timenow_adjust;			// Correction applied if we ever discover time went backwards
   1810 	mDNSs32  timenow;					// The time that this particular activation of the mDNS code started
   1811 	mDNSs32  timenow_last;				// The time the last time we ran
   1812 	mDNSs32  NextScheduledEvent;		// Derived from values below
   1813 	mDNSs32  ShutdownTime;				// Set when we're shutting down; allows us to skip some unnecessary steps
   1814 	mDNSs32  SuppressSending;			// Don't send local-link mDNS packets during this time
   1815 	mDNSs32  NextCacheCheck;			// Next time to refresh cache record before it expires
   1816 	mDNSs32  NextScheduledQuery;		// Next time to send query in its exponential backoff sequence
   1817 	mDNSs32  NextScheduledProbe;		// Next time to probe for new authoritative record
   1818 	mDNSs32  NextScheduledResponse;		// Next time to send authoritative record(s) in responses
   1819 	mDNSs32  NextScheduledNATOp;		// Next time to send NAT-traversal packets
   1820 	mDNSs32  NextScheduledSPS;			// Next time to purge expiring Sleep Proxy records
   1821 	mDNSs32  RandomQueryDelay;			// For de-synchronization of query packets on the wire
   1822 	mDNSu32  RandomReconfirmDelay;		// For de-synchronization of reconfirmation queries on the wire
   1823 	mDNSs32  PktNum;					// Unique sequence number assigned to each received packet
   1824 	mDNSu8   LocalRemoveEvents;			// Set if we may need to deliver remove events for local-only questions and/or local-only records
   1825 	mDNSu8   SleepState;				// Set if we're sleeping
   1826 	mDNSu8   SleepSeqNum;				// "Epoch number" of our current period of wakefulness
   1827 	mDNSu8   SystemWakeOnLANEnabled;	// Set if we want to register with a Sleep Proxy before going to sleep
   1828 	mDNSu8   SentSleepProxyRegistration;// Set if we registered (or tried to register) with a Sleep Proxy
   1829 	mDNSu8   SystemSleepOnlyIfWakeOnLAN;// Set if we may only sleep if we managed to register with a Sleep Proxy
   1830 	mDNSs32  AnnounceOwner;				// After waking from sleep, include OWNER option in packets until this time
   1831 	mDNSs32  DelaySleep;				// To inhibit re-sleeping too quickly right after wake
   1832 	mDNSs32  SleepLimit;				// Time window to allow deregistrations, etc.,
   1833 										// during which underying platform layer should inhibit system sleep
   1834 	mDNSs32  NextScheduledSPRetry;		// Time next sleep proxy registration action is required.
   1835 										// Only valid if SleepLimit is nonzero and DelaySleep is zero.
   1836 
   1837 	mDNSs32 NextScheduledStopTime;      // Next time to stop a question
   1838 
   1839 	// These fields only required for mDNS Searcher...
   1840 	DNSQuestion *Questions;				// List of all registered questions, active and inactive
   1841 	DNSQuestion *NewQuestions;			// Fresh questions not yet answered from cache
   1842 	DNSQuestion *CurrentQuestion;		// Next question about to be examined in AnswerLocalQuestions()
   1843 	DNSQuestion *LocalOnlyQuestions;	// Questions with InterfaceID set to mDNSInterface_LocalOnly or mDNSInterface_P2P
   1844 	DNSQuestion *NewLocalOnlyQuestions;	// Fresh local-only or P2P questions not yet answered
   1845 	DNSQuestion *RestartQuestion;		// Questions that are being restarted (stop followed by start)
   1846 	mDNSu32 rrcache_size;				// Total number of available cache entries
   1847 	mDNSu32 rrcache_totalused;			// Number of cache entries currently occupied
   1848 	mDNSu32 rrcache_active;				// Number of cache entries currently occupied by records that answer active questions
   1849 	mDNSu32 rrcache_report;
   1850 	CacheEntity *rrcache_free;
   1851 	CacheGroup *rrcache_hash[CACHE_HASH_SLOTS];
   1852 	mDNSs32  rrcache_nextcheck[CACHE_HASH_SLOTS];
   1853 
   1854 	AuthHash rrauth;
   1855 
   1856 	// Fields below only required for mDNS Responder...
   1857 	domainlabel nicelabel;				// Rich text label encoded using canonically precomposed UTF-8
   1858 	domainlabel hostlabel;				// Conforms to RFC 1034 "letter-digit-hyphen" ARPANET host name rules
   1859 	domainname  MulticastHostname;		// Fully Qualified "dot-local" Host Name, e.g. "Foo.local."
   1860 	UTF8str255  HIHardware;
   1861 	UTF8str255  HISoftware;
   1862 	AuthRecord  DeviceInfo;
   1863 	AuthRecord *ResourceRecords;
   1864 	AuthRecord *DuplicateRecords;		// Records currently 'on hold' because they are duplicates of existing records
   1865 	AuthRecord *NewLocalRecords;		// Fresh AuthRecords (public) not yet delivered to our local-only questions
   1866 	AuthRecord *CurrentRecord;			// Next AuthRecord about to be examined
   1867 	mDNSBool    NewLocalOnlyRecords;	// Fresh AuthRecords (local only) not yet delivered to our local questions
   1868 	NetworkInterfaceInfo *HostInterfaces;
   1869 	mDNSs32 ProbeFailTime;
   1870 	mDNSu32 NumFailedProbes;
   1871 	mDNSs32 SuppressProbes;
   1872 
   1873 	// Unicast-specific data
   1874 	mDNSs32           NextuDNSEvent;		// uDNS next event
   1875 	mDNSs32           NextSRVUpdate;        // Time to perform delayed update
   1876 
   1877 	DNSServer        *DNSServers;           // list of DNS servers
   1878 	McastResolver    *McastResolvers;       // list of Mcast Resolvers
   1879 
   1880 	mDNSAddr          Router;
   1881 	mDNSAddr          AdvertisedV4;         // IPv4 address pointed to by hostname
   1882 	mDNSAddr          AdvertisedV6;         // IPv6 address pointed to by hostname
   1883 
   1884 	DomainAuthInfo   *AuthInfoList;         // list of domains requiring authentication for updates
   1885 
   1886 	DNSQuestion       ReverseMap;           // Reverse-map query to find static hostname for service target
   1887 	DNSQuestion       AutomaticBrowseDomainQ;
   1888 	domainname        StaticHostname;       // Current answer to reverse-map query
   1889 	domainname        FQDN;
   1890 	HostnameInfo     *Hostnames;            // List of registered hostnames + hostname metadata
   1891 	mDNSv6Addr        AutoTunnelHostAddr;	// IPv6 address advertised for AutoTunnel services on this machine
   1892 	mDNSBool          AutoTunnelHostAddrActive;
   1893 	// AutoTunnel Relay address has two distinct uses
   1894 	// AutoTunnelRelayAddrIn: If non-zero, it means that this host can be reached (inbound connection) through the relay
   1895 	// AutoTunnelRelayAddrOut: If non-zero, it means that this host can use the relay to reach (outbound connection) the
   1896 	// other hosts through the relay
   1897 	mDNSv6Addr        AutoTunnelRelayAddrIn;
   1898 	mDNSv6Addr        AutoTunnelRelayAddrOut;
   1899 	domainlabel       AutoTunnelLabel;		// Used to construct hostname for *IPv4* address of tunnel endpoints
   1900 
   1901 	mDNSBool          StartWABQueries;		// Start WAB queries for the purpose of domain enumeration
   1902 	mDNSBool          RegisterAutoTunnel6;
   1903 
   1904 	// NAT-Traversal fields
   1905 	NATTraversalInfo  LLQNAT;					// Single shared NAT Traversal to receive inbound LLQ notifications
   1906 	NATTraversalInfo *NATTraversals;
   1907 	NATTraversalInfo *CurrentNATTraversal;
   1908 	mDNSs32           retryIntervalGetAddr;		// delta between time sent and retry
   1909 	mDNSs32           retryGetAddr;				// absolute time when we retry
   1910 	mDNSv4Addr        ExternalAddress;
   1911 
   1912 	UDPSocket        *NATMcastRecvskt;			// For receiving NAT-PMP AddrReply multicasts from router on port 5350
   1913 	mDNSu32           LastNATupseconds;			// NAT engine uptime in seconds, from most recent NAT packet
   1914 	mDNSs32           LastNATReplyLocalTime;	// Local time in ticks when most recent NAT packet was received
   1915 	mDNSu16           LastNATMapResultCode;		// Most recent error code for mappings
   1916 
   1917 	tcpLNTInfo        tcpAddrInfo;				// legacy NAT traversal TCP connection info for external address
   1918 	tcpLNTInfo        tcpDeviceInfo;			// legacy NAT traversal TCP connection info for device info
   1919 	tcpLNTInfo       *tcpInfoUnmapList;			// list of pending unmap requests
   1920 	mDNSInterfaceID   UPnPInterfaceID;
   1921 	UDPSocket        *SSDPSocket;               // For SSDP request/response
   1922 	mDNSBool          SSDPWANPPPConnection;     // whether we should send the SSDP query for WANIPConnection or WANPPPConnection
   1923 	mDNSIPPort        UPnPRouterPort;			// port we send discovery messages to
   1924 	mDNSIPPort        UPnPSOAPPort;				// port we send SOAP messages to
   1925 	mDNSu8           *UPnPRouterURL;			// router's URL string
   1926 	mDNSBool          UPnPWANPPPConnection;     // whether we're using WANIPConnection or WANPPPConnection
   1927 	mDNSu8           *UPnPSOAPURL;				// router's SOAP control URL string
   1928 	mDNSu8           *UPnPRouterAddressString;	// holds both the router's address and port
   1929 	mDNSu8           *UPnPSOAPAddressString;	// holds both address and port for SOAP messages
   1930 
   1931 	// Sleep Proxy Server fields
   1932 	mDNSu8            SPSType;					// 0 = off, 10-99 encodes desirability metric
   1933 	mDNSu8            SPSPortability;			// 10-99
   1934 	mDNSu8            SPSMarginalPower;			// 10-99
   1935 	mDNSu8            SPSTotalPower;			// 10-99
   1936 	mDNSu8            SPSState;					// 0 = off, 1 = running, 2 = shutting down, 3 = suspended during sleep
   1937 	mDNSInterfaceID   SPSProxyListChanged;
   1938 	UDPSocket        *SPSSocket;
   1939 	ServiceRecordSet  SPSRecords;
   1940 	mDNSQuestionCallback *SPSBrowseCallback;    // So the platform layer can do something useful with SPS browse results
   1941 	int               ProxyRecords;				// Total number of records we're holding as proxy
   1942 	#define           MAX_PROXY_RECORDS 10000	/* DOS protection: 400 machines at 25 records each */
   1943 
   1944 #if APPLE_OSX_mDNSResponder
   1945 	ClientTunnel     *TunnelClients;
   1946 	uuid_t           asl_uuid;					// uuid for ASL logging
   1947 	void		    *WCF;
   1948 #endif
   1949 
   1950 	// Fixed storage, to avoid creating large objects on the stack
   1951 	// The imsg is declared as a union with a pointer type to enforce CPU-appropriate alignment
   1952 	union { DNSMessage m; void *p; } imsg;  // Incoming message received from wire
   1953 	DNSMessage        omsg;                 // Outgoing message we're building
   1954 	LargeCacheRecord  rec;                  // Resource Record extracted from received message
   1955 	};
   1956 
   1957 #define FORALL_CACHERECORDS(SLOT,CG,CR)                           \
   1958 	for ((SLOT) = 0; (SLOT) < CACHE_HASH_SLOTS; (SLOT)++)         \
   1959 		for ((CG)=m->rrcache_hash[(SLOT)]; (CG); (CG)=(CG)->next) \
   1960 			for ((CR) = (CG)->members; (CR); (CR)=(CR)->next)
   1961 
   1962 // ***************************************************************************
   1963 #if 0
   1964 #pragma mark -
   1965 #pragma mark - Useful Static Constants
   1966 #endif
   1967 
   1968 extern const mDNSInterfaceID mDNSInterface_Any;				// Zero
   1969 extern const mDNSInterfaceID mDNSInterface_LocalOnly;		// Special value
   1970 extern const mDNSInterfaceID mDNSInterface_Unicast;			// Special value
   1971 extern const mDNSInterfaceID mDNSInterfaceMark;				// Special value
   1972 extern const mDNSInterfaceID mDNSInterface_P2P;				// Special value
   1973 
   1974 extern const mDNSIPPort   DiscardPort;
   1975 extern const mDNSIPPort   SSHPort;
   1976 extern const mDNSIPPort   UnicastDNSPort;
   1977 extern const mDNSIPPort   SSDPPort;
   1978 extern const mDNSIPPort   IPSECPort;
   1979 extern const mDNSIPPort   NSIPCPort;
   1980 extern const mDNSIPPort   NATPMPAnnouncementPort;
   1981 extern const mDNSIPPort   NATPMPPort;
   1982 extern const mDNSIPPort   DNSEXTPort;
   1983 extern const mDNSIPPort   MulticastDNSPort;
   1984 extern const mDNSIPPort   LoopbackIPCPort;
   1985 extern const mDNSIPPort   PrivateDNSPort;
   1986 
   1987 extern const OwnerOptData    zeroOwner;
   1988 
   1989 extern const mDNSIPPort      zeroIPPort;
   1990 extern const mDNSv4Addr      zerov4Addr;
   1991 extern const mDNSv6Addr      zerov6Addr;
   1992 extern const mDNSEthAddr     zeroEthAddr;
   1993 extern const mDNSv4Addr      onesIPv4Addr;
   1994 extern const mDNSv6Addr      onesIPv6Addr;
   1995 extern const mDNSEthAddr     onesEthAddr;
   1996 extern const mDNSAddr        zeroAddr;
   1997 
   1998 extern const mDNSv4Addr   AllDNSAdminGroup;
   1999 extern const mDNSv4Addr   AllHosts_v4;
   2000 extern const mDNSv6Addr   AllHosts_v6;
   2001 extern const mDNSv6Addr   NDP_prefix;
   2002 extern const mDNSEthAddr  AllHosts_v6_Eth;
   2003 extern const mDNSAddr     AllDNSLinkGroup_v4;
   2004 extern const mDNSAddr     AllDNSLinkGroup_v6;
   2005 
   2006 extern const mDNSOpaque16 zeroID;
   2007 extern const mDNSOpaque16 onesID;
   2008 extern const mDNSOpaque16 QueryFlags;
   2009 extern const mDNSOpaque16 uQueryFlags;
   2010 extern const mDNSOpaque16 ResponseFlags;
   2011 extern const mDNSOpaque16 UpdateReqFlags;
   2012 extern const mDNSOpaque16 UpdateRespFlags;
   2013 
   2014 extern const mDNSOpaque64 zeroOpaque64;
   2015 
   2016 extern mDNSBool StrictUnicastOrdering;
   2017 extern mDNSu8 NumUnicastDNSServers;
   2018 
   2019 #define localdomain           (*(const domainname *)"\x5" "local")
   2020 #define DeviceInfoName        (*(const domainname *)"\xC" "_device-info" "\x4" "_tcp")
   2021 #define SleepProxyServiceType (*(const domainname *)"\xC" "_sleep-proxy" "\x4" "_udp")
   2022 
   2023 // ***************************************************************************
   2024 #if 0
   2025 #pragma mark -
   2026 #pragma mark - Inline functions
   2027 #endif
   2028 
   2029 #if (defined(_MSC_VER))
   2030 	#define mDNSinline static __inline
   2031 #elif ((__GNUC__ > 2) || ((__GNUC__ == 2) && (__GNUC_MINOR__ >= 9)))
   2032 	#define mDNSinline static inline
   2033 #endif
   2034 
   2035 // If we're not doing inline functions, then this header needs to have the extern declarations
   2036 #if !defined(mDNSinline)
   2037 extern mDNSs32      NonZeroTime(mDNSs32 t);
   2038 extern mDNSu16      mDNSVal16(mDNSOpaque16 x);
   2039 extern mDNSOpaque16 mDNSOpaque16fromIntVal(mDNSu16 v);
   2040 #endif
   2041 
   2042 // If we're compiling the particular C file that instantiates our inlines, then we
   2043 // define "mDNSinline" (to empty string) so that we generate code in the following section
   2044 #if (!defined(mDNSinline) && mDNS_InstantiateInlines)
   2045 #define mDNSinline
   2046 #endif
   2047 
   2048 #ifdef mDNSinline
   2049 
   2050 mDNSinline mDNSs32 NonZeroTime(mDNSs32 t) { if (t) return(t); else return(1); }
   2051 
   2052 mDNSinline mDNSu16 mDNSVal16(mDNSOpaque16 x) { return((mDNSu16)((mDNSu16)x.b[0] <<  8 | (mDNSu16)x.b[1])); }
   2053 
   2054 mDNSinline mDNSOpaque16 mDNSOpaque16fromIntVal(mDNSu16 v)
   2055 	{
   2056 	mDNSOpaque16 x;
   2057 	x.b[0] = (mDNSu8)(v >> 8);
   2058 	x.b[1] = (mDNSu8)(v & 0xFF);
   2059 	return(x);
   2060 	}
   2061 
   2062 #endif
   2063 
   2064 // ***************************************************************************
   2065 #if 0
   2066 #pragma mark -
   2067 #pragma mark - Main Client Functions
   2068 #endif
   2069 
   2070 // Every client should call mDNS_Init, passing in storage for the mDNS object and the mDNS_PlatformSupport object.
   2071 //
   2072 // Clients that are only advertising services should use mDNS_Init_NoCache and mDNS_Init_ZeroCacheSize.
   2073 // Clients that plan to perform queries (mDNS_StartQuery, mDNS_StartBrowse, mDNS_StartResolveService, etc.)
   2074 // need to provide storage for the resource record cache, or the query calls will return 'mStatus_NoCache'.
   2075 // The rrcachestorage parameter is the address of memory for the resource record cache, and
   2076 // the rrcachesize parameter is the number of entries in the CacheRecord array passed in.
   2077 // (i.e. the size of the cache memory needs to be sizeof(CacheRecord) * rrcachesize).
   2078 // OS X 10.3 Panther uses an initial cache size of 64 entries, and then mDNSCore sends an
   2079 // mStatus_GrowCache message if it needs more.
   2080 //
   2081 // Most clients should use mDNS_Init_AdvertiseLocalAddresses. This causes mDNSCore to automatically
   2082 // create the correct address records for all the hosts interfaces. If you plan to advertise
   2083 // services being offered by the local machine, this is almost always what you want.
   2084 // There are two cases where you might use mDNS_Init_DontAdvertiseLocalAddresses:
   2085 // 1. A client-only device, that browses for services but doesn't advertise any of its own.
   2086 // 2. A proxy-registration service, that advertises services being offered by other machines, and takes
   2087 //    the appropriate steps to manually create the correct address records for those other machines.
   2088 // In principle, a proxy-like registration service could manually create address records for its own machine too,
   2089 // but this would be pointless extra effort when using mDNS_Init_AdvertiseLocalAddresses does that for you.
   2090 //
   2091 // Note that a client-only device that wishes to prohibit multicast advertisements (e.g. from
   2092 // higher-layer API calls) must also set DivertMulticastAdvertisements in the mDNS structure and
   2093 // advertise local address(es) on a loopback interface.
   2094 //
   2095 // When mDNS has finished setting up the client's callback is called
   2096 // A client can also spin and poll the mDNSPlatformStatus field to see when it changes from mStatus_Waiting to mStatus_NoError
   2097 //
   2098 // Call mDNS_StartExit to tidy up before exiting
   2099 // Because exiting may be an asynchronous process (e.g. if unicast records need to be deregistered)
   2100 // client layer may choose to wait until mDNS_ExitNow() returns true before calling mDNS_FinalExit().
   2101 //
   2102 // Call mDNS_Register with a completed AuthRecord object to register a resource record
   2103 // If the resource record type is kDNSRecordTypeUnique (or kDNSknownunique) then if a conflicting resource record is discovered,
   2104 // the resource record's mDNSRecordCallback will be called with error code mStatus_NameConflict. The callback should deregister
   2105 // the record, and may then try registering the record again after picking a new name (e.g. by automatically appending a number).
   2106 // Following deregistration, the RecordCallback will be called with result mStatus_MemFree to signal that it is safe to deallocate
   2107 // the record's storage (memory must be freed asynchronously to allow for goodbye packets and dynamic update deregistration).
   2108 //
   2109 // Call mDNS_StartQuery to initiate a query. mDNS will proceed to issue Multicast DNS query packets, and any time a response
   2110 // is received containing a record which matches the question, the DNSQuestion's mDNSAnswerCallback function will be called
   2111 // Call mDNS_StopQuery when no more answers are required
   2112 //
   2113 // Care should be taken on multi-threaded or interrupt-driven environments.
   2114 // The main mDNS routines call mDNSPlatformLock() on entry and mDNSPlatformUnlock() on exit;
   2115 // each platform layer needs to implement these appropriately for its respective platform.
   2116 // For example, if the support code on a particular platform implements timer callbacks at interrupt time, then
   2117 // mDNSPlatformLock/Unlock need to disable interrupts or do similar concurrency control to ensure that the mDNS
   2118 // code is not entered by an interrupt-time timer callback while in the middle of processing a client call.
   2119 
   2120 extern mStatus mDNS_Init      (mDNS *const m, mDNS_PlatformSupport *const p,
   2121 								CacheEntity *rrcachestorage, mDNSu32 rrcachesize,
   2122 								mDNSBool AdvertiseLocalAddresses,
   2123 								mDNSCallback *Callback, void *Context);
   2124 // See notes above on use of NoCache/ZeroCacheSize
   2125 #define mDNS_Init_NoCache                     mDNSNULL
   2126 #define mDNS_Init_ZeroCacheSize               0
   2127 // See notes above on use of Advertise/DontAdvertiseLocalAddresses
   2128 #define mDNS_Init_AdvertiseLocalAddresses     mDNStrue
   2129 #define mDNS_Init_DontAdvertiseLocalAddresses mDNSfalse
   2130 #define mDNS_Init_NoInitCallback              mDNSNULL
   2131 #define mDNS_Init_NoInitCallbackContext       mDNSNULL
   2132 
   2133 extern void    mDNS_ConfigChanged(mDNS *const m);
   2134 extern void    mDNS_GrowCache (mDNS *const m, CacheEntity *storage, mDNSu32 numrecords);
   2135 extern void    mDNS_GrowAuth (mDNS *const m, AuthEntity *storage, mDNSu32 numrecords);
   2136 extern void    mDNS_StartExit (mDNS *const m);
   2137 extern void    mDNS_FinalExit (mDNS *const m);
   2138 #define mDNS_Close(m) do { mDNS_StartExit(m); mDNS_FinalExit(m); } while(0)
   2139 #define mDNS_ExitNow(m, now) ((now) - (m)->ShutdownTime >= 0 || (!(m)->ResourceRecords))
   2140 
   2141 extern mDNSs32 mDNS_Execute   (mDNS *const m);
   2142 
   2143 extern mStatus mDNS_Register  (mDNS *const m, AuthRecord *const rr);
   2144 extern mStatus mDNS_Update    (mDNS *const m, AuthRecord *const rr, mDNSu32 newttl,
   2145 								const mDNSu16 newrdlength, RData *const newrdata, mDNSRecordUpdateCallback *Callback);
   2146 extern mStatus mDNS_Deregister(mDNS *const m, AuthRecord *const rr);
   2147 
   2148 extern mStatus mDNS_StartQuery(mDNS *const m, DNSQuestion *const question);
   2149 extern mStatus mDNS_StopQuery (mDNS *const m, DNSQuestion *const question);
   2150 extern mStatus mDNS_StopQueryWithRemoves(mDNS *const m, DNSQuestion *const question);
   2151 extern mStatus mDNS_Reconfirm (mDNS *const m, CacheRecord *const cacherr);
   2152 extern mStatus mDNS_ReconfirmByValue(mDNS *const m, ResourceRecord *const rr);
   2153 extern void    mDNS_PurgeCacheResourceRecord(mDNS *const m, CacheRecord *rr);
   2154 extern mDNSs32 mDNS_TimeNow(const mDNS *const m);
   2155 
   2156 extern mStatus mDNS_StartNATOperation(mDNS *const m, NATTraversalInfo *traversal);
   2157 extern mStatus mDNS_StopNATOperation(mDNS *const m, NATTraversalInfo *traversal);
   2158 extern mStatus mDNS_StopNATOperation_internal(mDNS *m, NATTraversalInfo *traversal);
   2159 
   2160 extern DomainAuthInfo *GetAuthInfoForName(mDNS *m, const domainname *const name);
   2161 
   2162 extern void    mDNS_UpdateAllowSleep(mDNS *const m);
   2163 
   2164 // ***************************************************************************
   2165 #if 0
   2166 #pragma mark -
   2167 #pragma mark - Platform support functions that are accessible to the client layer too
   2168 #endif
   2169 
   2170 extern mDNSs32  mDNSPlatformOneSecond;
   2171 
   2172 // ***************************************************************************
   2173 #if 0
   2174 #pragma mark -
   2175 #pragma mark - General utility and helper functions
   2176 #endif
   2177 
   2178 // mDNS_Dereg_normal is used for most calls to mDNS_Deregister_internal
   2179 // mDNS_Dereg_rapid is used to send one goodbye instead of three, when we want the memory available for reuse sooner
   2180 // mDNS_Dereg_conflict is used to indicate that this record is being forcibly deregistered because of a conflict
   2181 // mDNS_Dereg_repeat is used when cleaning up, for records that may have already been forcibly deregistered
   2182 typedef enum { mDNS_Dereg_normal, mDNS_Dereg_rapid, mDNS_Dereg_conflict, mDNS_Dereg_repeat } mDNS_Dereg_type;
   2183 
   2184 // mDNS_RegisterService is a single call to register the set of resource records associated with a given named service.
   2185 //
   2186 // mDNS_StartResolveService is single call which is equivalent to multiple calls to mDNS_StartQuery,
   2187 // to find the IP address, port number, and demultiplexing information for a given named service.
   2188 // As with mDNS_StartQuery, it executes asynchronously, and calls the ServiceInfoQueryCallback when the answer is
   2189 // found. After the service is resolved, the client should call mDNS_StopResolveService to complete the transaction.
   2190 // The client can also call mDNS_StopResolveService at any time to abort the transaction.
   2191 //
   2192 // mDNS_AddRecordToService adds an additional record to a Service Record Set.  This record may be deregistered
   2193 // via mDNS_RemoveRecordFromService, or by deregistering the service.  mDNS_RemoveRecordFromService is passed a
   2194 // callback to free the memory associated with the extra RR when it is safe to do so.  The ExtraResourceRecord
   2195 // object can be found in the record's context pointer.
   2196 
   2197 // mDNS_GetBrowseDomains is a special case of the mDNS_StartQuery call, where the resulting answers
   2198 // are a list of PTR records indicating (in the rdata) domains that are recommended for browsing.
   2199 // After getting the list of domains to browse, call mDNS_StopQuery to end the search.
   2200 // mDNS_GetDefaultBrowseDomain returns the name of the domain that should be highlighted by default.
   2201 //
   2202 // mDNS_GetRegistrationDomains and mDNS_GetDefaultRegistrationDomain are the equivalent calls to get the list
   2203 // of one or more domains that should be offered to the user as choices for where they may register their service,
   2204 // and the default domain in which to register in the case where the user has made no selection.
   2205 
   2206 extern void    mDNS_SetupResourceRecord(AuthRecord *rr, RData *RDataStorage, mDNSInterfaceID InterfaceID,
   2207                mDNSu16 rrtype, mDNSu32 ttl, mDNSu8 RecordType, AuthRecType artype, mDNSRecordCallback Callback, void *Context);
   2208 
   2209 // mDNS_RegisterService() flags parameter bit definitions
   2210 enum
   2211 	{
   2212 		regFlagIncludeP2P	= 0x1,	// include P2P interfaces when using mDNSInterface_Any
   2213 		regFlagKnownUnique	= 0x2	// client guarantees that SRV and TXT record names are unique
   2214 	};
   2215 
   2216 extern mStatus mDNS_RegisterService  (mDNS *const m, ServiceRecordSet *sr,
   2217                const domainlabel *const name, const domainname *const type, const domainname *const domain,
   2218                const domainname *const host, mDNSIPPort port, const mDNSu8 txtinfo[], mDNSu16 txtlen,
   2219                AuthRecord *SubTypes, mDNSu32 NumSubTypes,
   2220                mDNSInterfaceID InterfaceID, mDNSServiceCallback Callback, void *Context, mDNSu32 flags);
   2221 extern mStatus mDNS_AddRecordToService(mDNS *const m, ServiceRecordSet *sr, ExtraResourceRecord *extra, RData *rdata, mDNSu32 ttl,  mDNSu32 includeP2P);
   2222 extern mStatus mDNS_RemoveRecordFromService(mDNS *const m, ServiceRecordSet *sr, ExtraResourceRecord *extra, mDNSRecordCallback MemFreeCallback, void *Context);
   2223 extern mStatus mDNS_RenameAndReregisterService(mDNS *const m, ServiceRecordSet *const sr, const domainlabel *newname);
   2224 extern mStatus mDNS_DeregisterService_drt(mDNS *const m, ServiceRecordSet *sr, mDNS_Dereg_type drt);
   2225 #define mDNS_DeregisterService(M,S) mDNS_DeregisterService_drt((M), (S), mDNS_Dereg_normal)
   2226 
   2227 extern mStatus mDNS_RegisterNoSuchService(mDNS *const m, AuthRecord *const rr,
   2228                const domainlabel *const name, const domainname *const type, const domainname *const domain,
   2229                const domainname *const host,
   2230                const mDNSInterfaceID InterfaceID, mDNSRecordCallback Callback, void *Context, mDNSBool includeP2P);
   2231 #define        mDNS_DeregisterNoSuchService mDNS_Deregister
   2232 
   2233 extern void mDNS_SetupQuestion(DNSQuestion *const q, const mDNSInterfaceID InterfaceID, const domainname *const name,
   2234                const mDNSu16 qtype, mDNSQuestionCallback *const callback, void *const context);
   2235 
   2236 extern mStatus mDNS_StartBrowse(mDNS *const m, DNSQuestion *const question,
   2237                const domainname *const srv, const domainname *const domain,
   2238                const mDNSInterfaceID InterfaceID, mDNSBool ForceMCast, mDNSQuestionCallback *Callback, void *Context);
   2239 #define        mDNS_StopBrowse mDNS_StopQuery
   2240 
   2241 extern mStatus mDNS_StartResolveService(mDNS *const m, ServiceInfoQuery *query, ServiceInfo *info, mDNSServiceInfoQueryCallback *Callback, void *Context);
   2242 extern void    mDNS_StopResolveService (mDNS *const m, ServiceInfoQuery *query);
   2243 
   2244 typedef enum
   2245 	{
   2246 	mDNS_DomainTypeBrowse              = 0,
   2247 	mDNS_DomainTypeBrowseDefault       = 1,
   2248 	mDNS_DomainTypeBrowseAutomatic     = 2,
   2249 	mDNS_DomainTypeRegistration        = 3,
   2250 	mDNS_DomainTypeRegistrationDefault = 4,
   2251 
   2252 	mDNS_DomainTypeMax = 4
   2253 	} mDNS_DomainType;
   2254 
   2255 extern const char *const mDNS_DomainTypeNames[];
   2256 
   2257 extern mStatus mDNS_GetDomains(mDNS *const m, DNSQuestion *const question, mDNS_DomainType DomainType, const domainname *dom,
   2258 								const mDNSInterfaceID InterfaceID, mDNSQuestionCallback *Callback, void *Context);
   2259 #define        mDNS_StopGetDomains mDNS_StopQuery
   2260 extern mStatus mDNS_AdvertiseDomains(mDNS *const m, AuthRecord *rr, mDNS_DomainType DomainType, const mDNSInterfaceID InterfaceID, char *domname);
   2261 #define        mDNS_StopAdvertiseDomains mDNS_Deregister
   2262 
   2263 extern mDNSOpaque16 mDNS_NewMessageID(mDNS *const m);
   2264 extern mDNSBool mDNS_AddressIsLocalSubnet(mDNS *const m, const mDNSInterfaceID InterfaceID, const mDNSAddr *addr);
   2265 
   2266 extern DNSServer *GetServerForName(mDNS *m, const domainname *name, mDNSInterfaceID InterfaceID);
   2267 extern DNSServer *GetServerForQuestion(mDNS *m, DNSQuestion *question);
   2268 extern mDNSu32 SetValidDNSServers(mDNS *m, DNSQuestion *question);
   2269 
   2270 // ***************************************************************************
   2271 #if 0
   2272 #pragma mark -
   2273 #pragma mark - DNS name utility functions
   2274 #endif
   2275 
   2276 // In order to expose the full capabilities of the DNS protocol (which allows any arbitrary eight-bit values
   2277 // in domain name labels, including unlikely characters like ascii nulls and even dots) all the mDNS APIs
   2278 // work with DNS's native length-prefixed strings. For convenience in C, the following utility functions
   2279 // are provided for converting between C's null-terminated strings and DNS's length-prefixed strings.
   2280 
   2281 // Assignment
   2282 // A simple C structure assignment of a domainname can cause a protection fault by accessing unmapped memory,
   2283 // because that object is defined to be 256 bytes long, but not all domainname objects are truly the full size.
   2284 // This macro uses mDNSPlatformMemCopy() to make sure it only touches the actual bytes that are valid.
   2285 #define AssignDomainName(DST, SRC) do { mDNSu16 len__ = DomainNameLength((SRC)); \
   2286 	if (len__ <= MAX_DOMAIN_NAME) mDNSPlatformMemCopy((DST)->c, (SRC)->c, len__); else (DST)->c[0] = 0; } while(0)
   2287 
   2288 // Comparison functions
   2289 #define SameDomainLabelCS(A,B) ((A)[0] == (B)[0] && mDNSPlatformMemSame((A)+1, (B)+1, (A)[0]))
   2290 extern mDNSBool SameDomainLabel(const mDNSu8 *a, const mDNSu8 *b);
   2291 extern mDNSBool SameDomainName(const domainname *const d1, const domainname *const d2);
   2292 extern mDNSBool SameDomainNameCS(const domainname *const d1, const domainname *const d2);
   2293 typedef mDNSBool DomainNameComparisonFn(const domainname *const d1, const domainname *const d2);
   2294 extern mDNSBool IsLocalDomain(const domainname *d);     // returns true for domains that by default should be looked up using link-local multicast
   2295 
   2296 #define StripFirstLabel(X) ((const domainname *)&(X)->c[(X)->c[0] ? 1 + (X)->c[0] : 0])
   2297 
   2298 #define FirstLabel(X)  ((const domainlabel *)(X))
   2299 #define SecondLabel(X) ((const domainlabel *)StripFirstLabel(X))
   2300 #define ThirdLabel(X)  ((const domainlabel *)StripFirstLabel(StripFirstLabel(X)))
   2301 
   2302 extern const mDNSu8 *LastLabel(const domainname *d);
   2303 
   2304 // Get total length of domain name, in native DNS format, including terminal root label
   2305 //   (e.g. length of "com." is 5 (length byte, three data bytes, final zero)
   2306 extern mDNSu16  DomainNameLengthLimit(const domainname *const name, const mDNSu8 *limit);
   2307 #define DomainNameLength(name) DomainNameLengthLimit((name), (name)->c + MAX_DOMAIN_NAME)
   2308 
   2309 // Append functions to append one or more labels to an existing native format domain name:
   2310 //   AppendLiteralLabelString adds a single label from a literal C string, with no escape character interpretation.
   2311 //   AppendDNSNameString      adds zero or more labels from a C string using conventional DNS dots-and-escaping interpretation
   2312 //   AppendDomainLabel        adds a single label from a native format domainlabel
   2313 //   AppendDomainName         adds zero or more labels from a native format domainname
   2314 extern mDNSu8  *AppendLiteralLabelString(domainname *const name, const char *cstr);
   2315 extern mDNSu8  *AppendDNSNameString     (domainname *const name, const char *cstr);
   2316 extern mDNSu8  *AppendDomainLabel       (domainname *const name, const domainlabel *const label);
   2317 extern mDNSu8  *AppendDomainName        (domainname *const name, const domainname *const append);
   2318 
   2319 // Convert from null-terminated string to native DNS format:
   2320 //   The DomainLabel form makes a single label from a literal C string, with no escape character interpretation.
   2321 //   The DomainName form makes native format domain name from a C string using conventional DNS interpretation:
   2322 //     dots separate labels, and within each label, '\.' represents a literal dot, '\\' represents a literal
   2323 //     backslash and backslash with three decimal digits (e.g. \000) represents an arbitrary byte value.
   2324 extern mDNSBool MakeDomainLabelFromLiteralString(domainlabel *const label, const char *cstr);
   2325 extern mDNSu8  *MakeDomainNameFromDNSNameString (domainname  *const name,  const char *cstr);
   2326 
   2327 // Convert native format domainlabel or domainname back to C string format
   2328 // IMPORTANT:
   2329 // When using ConvertDomainLabelToCString, the target buffer must be MAX_ESCAPED_DOMAIN_LABEL (254) bytes long
   2330 // to guarantee there will be no buffer overrun. It is only safe to use a buffer shorter than this in rare cases
   2331 // where the label is known to be constrained somehow (for example, if the label is known to be either "_tcp" or "_udp").
   2332 // Similarly, when using ConvertDomainNameToCString, the target buffer must be MAX_ESCAPED_DOMAIN_NAME (1009) bytes long.
   2333 // See definitions of MAX_ESCAPED_DOMAIN_LABEL and MAX_ESCAPED_DOMAIN_NAME for more detailed explanation.
   2334 extern char    *ConvertDomainLabelToCString_withescape(const domainlabel *const name, char *cstr, char esc);
   2335 #define         ConvertDomainLabelToCString_unescaped(D,C) ConvertDomainLabelToCString_withescape((D), (C), 0)
   2336 #define         ConvertDomainLabelToCString(D,C)           ConvertDomainLabelToCString_withescape((D), (C), '\\')
   2337 extern char    *ConvertDomainNameToCString_withescape(const domainname *const name, char *cstr, char esc);
   2338 #define         ConvertDomainNameToCString_unescaped(D,C) ConvertDomainNameToCString_withescape((D), (C), 0)
   2339 #define         ConvertDomainNameToCString(D,C)           ConvertDomainNameToCString_withescape((D), (C), '\\')
   2340 
   2341 extern void     ConvertUTF8PstringToRFC1034HostLabel(const mDNSu8 UTF8Name[], domainlabel *const hostlabel);
   2342 
   2343 extern mDNSu8  *ConstructServiceName(domainname *const fqdn, const domainlabel *name, const domainname *type, const domainname *const domain);
   2344 extern mDNSBool DeconstructServiceName(const domainname *const fqdn, domainlabel *const name, domainname *const type, domainname *const domain);
   2345 
   2346 // Note: Some old functions have been replaced by more sensibly-named versions.
   2347 // You can uncomment the hash-defines below if you don't want to have to change your source code right away.
   2348 // When updating your code, note that (unlike the old versions) *all* the new routines take the target object
   2349 // as their first parameter.
   2350 //#define ConvertCStringToDomainName(SRC,DST)  MakeDomainNameFromDNSNameString((DST),(SRC))
   2351 //#define ConvertCStringToDomainLabel(SRC,DST) MakeDomainLabelFromLiteralString((DST),(SRC))
   2352 //#define AppendStringLabelToName(DST,SRC)     AppendLiteralLabelString((DST),(SRC))
   2353 //#define AppendStringNameToName(DST,SRC)      AppendDNSNameString((DST),(SRC))
   2354 //#define AppendDomainLabelToName(DST,SRC)     AppendDomainLabel((DST),(SRC))
   2355 //#define AppendDomainNameToName(DST,SRC)      AppendDomainName((DST),(SRC))
   2356 
   2357 // ***************************************************************************
   2358 #if 0
   2359 #pragma mark -
   2360 #pragma mark - Other utility functions and macros
   2361 #endif
   2362 
   2363 // mDNS_vsnprintf/snprintf return the number of characters written, excluding the final terminating null.
   2364 // The output is always null-terminated: for example, if the output turns out to be exactly buflen long,
   2365 // then the output will be truncated by one character to allow space for the terminating null.
   2366 // Unlike standard C vsnprintf/snprintf, they return the number of characters *actually* written,
   2367 // not the number of characters that *would* have been printed were buflen unlimited.
   2368 extern mDNSu32 mDNS_vsnprintf(char *sbuffer, mDNSu32 buflen, const char *fmt, va_list arg);
   2369 extern mDNSu32 mDNS_snprintf(char *sbuffer, mDNSu32 buflen, const char *fmt, ...) IS_A_PRINTF_STYLE_FUNCTION(3,4);
   2370 extern mDNSu32 NumCacheRecordsForInterfaceID(const mDNS *const m, mDNSInterfaceID id);
   2371 extern char *DNSTypeName(mDNSu16 rrtype);
   2372 extern char *GetRRDisplayString_rdb(const ResourceRecord *const rr, const RDataBody *const rd1, char *const buffer);
   2373 #define RRDisplayString(m, rr) GetRRDisplayString_rdb(rr, &(rr)->rdata->u, (m)->MsgBuffer)
   2374 #define ARDisplayString(m, rr) GetRRDisplayString_rdb(&(rr)->resrec, &(rr)->resrec.rdata->u, (m)->MsgBuffer)
   2375 #define CRDisplayString(m, rr) GetRRDisplayString_rdb(&(rr)->resrec, &(rr)->resrec.rdata->u, (m)->MsgBuffer)
   2376 extern mDNSBool mDNSSameAddress(const mDNSAddr *ip1, const mDNSAddr *ip2);
   2377 extern void IncrementLabelSuffix(domainlabel *name, mDNSBool RichText);
   2378 extern mDNSBool mDNSv4AddrIsRFC1918(mDNSv4Addr *addr);  // returns true for RFC1918 private addresses
   2379 #define mDNSAddrIsRFC1918(X) ((X)->type == mDNSAddrType_IPv4 && mDNSv4AddrIsRFC1918(&(X)->ip.v4))
   2380 
   2381 #define mDNSSameIPPort(A,B)      ((A).NotAnInteger == (B).NotAnInteger)
   2382 #define mDNSSameOpaque16(A,B)    ((A).NotAnInteger == (B).NotAnInteger)
   2383 #define mDNSSameOpaque32(A,B)    ((A).NotAnInteger == (B).NotAnInteger)
   2384 #define mDNSSameOpaque64(A,B)    ((A)->l[0] == (B)->l[0] && (A)->l[1] == (B)->l[1])
   2385 
   2386 #define mDNSSameIPv4Address(A,B) ((A).NotAnInteger == (B).NotAnInteger)
   2387 #define mDNSSameIPv6Address(A,B) ((A).l[0] == (B).l[0] && (A).l[1] == (B).l[1] && (A).l[2] == (B).l[2] && (A).l[3] == (B).l[3])
   2388 #define mDNSSameEthAddress(A,B)  ((A)->w[0] == (B)->w[0] && (A)->w[1] == (B)->w[1] && (A)->w[2] == (B)->w[2])
   2389 
   2390 #define mDNSIPPortIsZero(A)      ((A).NotAnInteger                            == 0)
   2391 #define mDNSOpaque16IsZero(A)    ((A).NotAnInteger                            == 0)
   2392 #define mDNSOpaque64IsZero(A)    (((A)->l[0] | (A)->l[1]                    ) == 0)
   2393 #define mDNSIPv4AddressIsZero(A) ((A).NotAnInteger                            == 0)
   2394 #define mDNSIPv6AddressIsZero(A) (((A).l[0] | (A).l[1] | (A).l[2] | (A).l[3]) == 0)
   2395 #define mDNSEthAddressIsZero(A)  (((A).w[0] | (A).w[1] | (A).w[2]           ) == 0)
   2396 
   2397 #define mDNSIPv4AddressIsOnes(A) ((A).NotAnInteger == 0xFFFFFFFF)
   2398 #define mDNSIPv6AddressIsOnes(A) (((A).l[0] & (A).l[1] & (A).l[2] & (A).l[3]) == 0xFFFFFFFF)
   2399 
   2400 #define mDNSAddressIsAllDNSLinkGroup(X) (                                                            \
   2401 	((X)->type == mDNSAddrType_IPv4 && mDNSSameIPv4Address((X)->ip.v4, AllDNSLinkGroup_v4.ip.v4)) || \
   2402 	((X)->type == mDNSAddrType_IPv6 && mDNSSameIPv6Address((X)->ip.v6, AllDNSLinkGroup_v6.ip.v6))    )
   2403 
   2404 #define mDNSAddressIsZero(X) (                                                \
   2405 	((X)->type == mDNSAddrType_IPv4 && mDNSIPv4AddressIsZero((X)->ip.v4))  || \
   2406 	((X)->type == mDNSAddrType_IPv6 && mDNSIPv6AddressIsZero((X)->ip.v6))     )
   2407 
   2408 #define mDNSAddressIsValidNonZero(X) (                                        \
   2409 	((X)->type == mDNSAddrType_IPv4 && !mDNSIPv4AddressIsZero((X)->ip.v4)) || \
   2410 	((X)->type == mDNSAddrType_IPv6 && !mDNSIPv6AddressIsZero((X)->ip.v6))    )
   2411 
   2412 #define mDNSAddressIsOnes(X) (                                                \
   2413 	((X)->type == mDNSAddrType_IPv4 && mDNSIPv4AddressIsOnes((X)->ip.v4))  || \
   2414 	((X)->type == mDNSAddrType_IPv6 && mDNSIPv6AddressIsOnes((X)->ip.v6))     )
   2415 
   2416 #define mDNSAddressIsValid(X) (                                                                                             \
   2417 	((X)->type == mDNSAddrType_IPv4) ? !(mDNSIPv4AddressIsZero((X)->ip.v4) || mDNSIPv4AddressIsOnes((X)->ip.v4)) :          \
   2418 	((X)->type == mDNSAddrType_IPv6) ? !(mDNSIPv6AddressIsZero((X)->ip.v6) || mDNSIPv6AddressIsOnes((X)->ip.v6)) : mDNSfalse)
   2419 
   2420 #define mDNSv4AddressIsLinkLocal(X) ((X)->b[0] ==  169 &&  (X)->b[1]         ==  254)
   2421 #define mDNSv6AddressIsLinkLocal(X) ((X)->b[0] == 0xFE && ((X)->b[1] & 0xC0) == 0x80)
   2422 
   2423 #define mDNSAddressIsLinkLocal(X)  (                                                    \
   2424 	((X)->type == mDNSAddrType_IPv4) ? mDNSv4AddressIsLinkLocal(&(X)->ip.v4) :          \
   2425 	((X)->type == mDNSAddrType_IPv6) ? mDNSv6AddressIsLinkLocal(&(X)->ip.v6) : mDNSfalse)
   2426 
   2427 #define mDNSv4AddressIsLoopback(X) ((X)->b[0] == 127 && (X)->b[1] == 0 && (X)->b[2] == 0 && (X)->b[3] == 1)
   2428 #define mDNSv6AddressIsLoopback(X) ((((X)->l[0] | (X)->l[1] | (X)->l[2]) == 0) && ((X)->b[12] == 0 && (X)->b[13] == 0 && (X)->b[14] == 0 && (X)->b[15] == 1))
   2429 
   2430 // ***************************************************************************
   2431 #if 0
   2432 #pragma mark -
   2433 #pragma mark - Authentication Support
   2434 #endif
   2435 
   2436 // Unicast DNS and Dynamic Update specific Client Calls
   2437 //
   2438 // mDNS_SetSecretForDomain tells the core to authenticate (via TSIG with an HMAC_MD5 hash of the shared secret)
   2439 // when dynamically updating a given zone (and its subdomains).  The key used in authentication must be in
   2440 // domain name format.  The shared secret must be a null-terminated base64 encoded string.  A minimum size of
   2441 // 16 bytes (128 bits) is recommended for an MD5 hash as per RFC 2485.
   2442 // Calling this routine multiple times for a zone replaces previously entered values.  Call with a NULL key
   2443 // to disable authentication for the zone.  A non-NULL autoTunnelPrefix means this is an AutoTunnel domain,
   2444 // and the value is prepended to the IPSec identifier (used for key lookup)
   2445 
   2446 extern mStatus mDNS_SetSecretForDomain(mDNS *m, DomainAuthInfo *info,
   2447 	const domainname *domain, const domainname *keyname, const char *b64keydata, const domainname *hostname, mDNSIPPort *port, const char *autoTunnelPrefix);
   2448 
   2449 extern void RecreateNATMappings(mDNS *const m);
   2450 
   2451 // Hostname/Unicast Interface Configuration
   2452 
   2453 // All hostnames advertised point to one IPv4 address and/or one IPv6 address, set via SetPrimaryInterfaceInfo.  Invoking this routine
   2454 // updates all existing hostnames to point to the new address.
   2455 
   2456 // A hostname is added via AddDynDNSHostName, which points to the primary interface's v4 and/or v6 addresss
   2457 
   2458 // The status callback is invoked to convey success or failure codes - the callback should not modify the AuthRecord or free memory.
   2459 // Added hostnames may be removed (deregistered) via mDNS_RemoveDynDNSHostName.
   2460 
   2461 // Host domains added prior to specification of the primary interface address and computer name will be deferred until
   2462 // these values are initialized.
   2463 
   2464 // DNS servers used to resolve unicast queries are specified by mDNS_AddDNSServer.
   2465 // For "split" DNS configurations, in which queries for different domains are sent to different servers (e.g. VPN and external),
   2466 // a domain may be associated with a DNS server.  For standard configurations, specify the root label (".") or NULL.
   2467 
   2468 extern void mDNS_AddDynDNSHostName(mDNS *m, const domainname *fqdn, mDNSRecordCallback *StatusCallback, const void *StatusContext);
   2469 extern void mDNS_RemoveDynDNSHostName(mDNS *m, const domainname *fqdn);
   2470 extern void mDNS_SetPrimaryInterfaceInfo(mDNS *m, const mDNSAddr *v4addr,  const mDNSAddr *v6addr, const mDNSAddr *router);
   2471 extern DNSServer *mDNS_AddDNSServer(mDNS *const m, const domainname *d, const mDNSInterfaceID interface, const mDNSAddr *addr, const mDNSIPPort port, mDNSBool scoped, mDNSu32 timeout);
   2472 extern void PenalizeDNSServer(mDNS *const m, DNSQuestion *q);
   2473 extern void mDNS_AddSearchDomain(const domainname *const domain, mDNSInterfaceID InterfaceID);
   2474 
   2475 extern McastResolver *mDNS_AddMcastResolver(mDNS *const m, const domainname *d, const mDNSInterfaceID interface, mDNSu32 timeout);
   2476 
   2477 // We use ((void *)0) here instead of mDNSNULL to avoid compile warnings on gcc 4.2
   2478 #define mDNS_AddSearchDomain_CString(X, I) \
   2479 	do { domainname d__; if (((X) != (void*)0) && MakeDomainNameFromDNSNameString(&d__, (X)) && d__.c[0]) mDNS_AddSearchDomain(&d__, I); } while(0)
   2480 
   2481 // Routines called by the core, exported by DNSDigest.c
   2482 
   2483 // Convert an arbitrary base64 encoded key key into an HMAC key (stored in AuthInfo struct)
   2484 extern mDNSs32 DNSDigest_ConstructHMACKeyfromBase64(DomainAuthInfo *info, const char *b64key);
   2485 
   2486 // sign a DNS message.  The message must be complete, with all values in network byte order.  end points to the end
   2487 // of the message, and is modified by this routine.  numAdditionals is a pointer to the number of additional
   2488 // records in HOST byte order, which is incremented upon successful completion of this routine.  The function returns
   2489 // the new end pointer on success, and NULL on failure.
   2490 extern void DNSDigest_SignMessage(DNSMessage *msg, mDNSu8 **end, DomainAuthInfo *info, mDNSu16 tcode);
   2491 
   2492 #define SwapDNSHeaderBytes(M) do { \
   2493     (M)->h.numQuestions   = (mDNSu16)((mDNSu8 *)&(M)->h.numQuestions  )[0] << 8 | ((mDNSu8 *)&(M)->h.numQuestions  )[1]; \
   2494     (M)->h.numAnswers     = (mDNSu16)((mDNSu8 *)&(M)->h.numAnswers    )[0] << 8 | ((mDNSu8 *)&(M)->h.numAnswers    )[1]; \
   2495     (M)->h.numAuthorities = (mDNSu16)((mDNSu8 *)&(M)->h.numAuthorities)[0] << 8 | ((mDNSu8 *)&(M)->h.numAuthorities)[1]; \
   2496     (M)->h.numAdditionals = (mDNSu16)((mDNSu8 *)&(M)->h.numAdditionals)[0] << 8 | ((mDNSu8 *)&(M)->h.numAdditionals)[1]; \
   2497     } while (0)
   2498 
   2499 #define DNSDigest_SignMessageHostByteOrder(M,E,INFO) \
   2500 	do { SwapDNSHeaderBytes(M); DNSDigest_SignMessage((M), (E), (INFO), 0); SwapDNSHeaderBytes(M); } while (0)
   2501 
   2502 // verify a DNS message.  The message must be complete, with all values in network byte order.  end points to the
   2503 // end of the record.  tsig is a pointer to the resource record that contains the TSIG OPT record.  info is
   2504 // the matching key to use for verifying the message.  This function expects that the additionals member
   2505 // of the DNS message header has already had one subtracted from it.
   2506 extern mDNSBool DNSDigest_VerifyMessage(DNSMessage *msg, mDNSu8 *end, LargeCacheRecord *tsig, DomainAuthInfo *info, mDNSu16 *rcode, mDNSu16 *tcode);
   2507 
   2508 // ***************************************************************************
   2509 #if 0
   2510 #pragma mark -
   2511 #pragma mark - PlatformSupport interface
   2512 #endif
   2513 
   2514 // This section defines the interface to the Platform Support layer.
   2515 // Normal client code should not use any of types defined here, or directly call any of the functions defined here.
   2516 // The definitions are placed here because sometimes clients do use these calls indirectly, via other supported client operations.
   2517 // For example, AssignDomainName is a macro defined using mDNSPlatformMemCopy()
   2518 
   2519 // Every platform support module must provide the following functions.
   2520 // mDNSPlatformInit() typically opens a communication endpoint, and starts listening for mDNS packets.
   2521 // When Setup is complete, the platform support layer calls mDNSCoreInitComplete().
   2522 // mDNSPlatformSendUDP() sends one UDP packet
   2523 // When a packet is received, the PlatformSupport code calls mDNSCoreReceive()
   2524 // mDNSPlatformClose() tidies up on exit
   2525 //
   2526 // Note: mDNSPlatformMemAllocate/mDNSPlatformMemFree are only required for handling oversized resource records and unicast DNS.
   2527 // If your target platform has a well-defined specialized application, and you know that all the records it uses
   2528 // are InlineCacheRDSize or less, then you can just make a simple mDNSPlatformMemAllocate() stub that always returns
   2529 // NULL. InlineCacheRDSize is a compile-time constant, which is set by default to 68. If you need to handle records
   2530 // a little larger than this and you don't want to have to implement run-time allocation and freeing, then you
   2531 // can raise the value of this constant to a suitable value (at the expense of increased memory usage).
   2532 //
   2533 // USE CAUTION WHEN CALLING mDNSPlatformRawTime: The m->timenow_adjust correction factor needs to be added
   2534 // Generally speaking:
   2535 // Code that's protected by the main mDNS lock should just use the m->timenow value
   2536 // Code outside the main mDNS lock should use mDNS_TimeNow(m) to get properly adjusted time
   2537 // In certain cases there may be reasons why it's necessary to get the time without taking the lock first
   2538 // (e.g. inside the routines that are doing the locking and unlocking, where a call to get the lock would result in a
   2539 // recursive loop); in these cases use mDNS_TimeNow_NoLock(m) to get mDNSPlatformRawTime with the proper correction factor added.
   2540 //
   2541 // mDNSPlatformUTC returns the time, in seconds, since Jan 1st 1970 UTC and is required for generating TSIG records
   2542 
   2543 extern mStatus  mDNSPlatformInit        (mDNS *const m);
   2544 extern void     mDNSPlatformClose       (mDNS *const m);
   2545 extern mStatus  mDNSPlatformSendUDP(const mDNS *const m, const void *const msg, const mDNSu8 *const end,
   2546 mDNSInterfaceID InterfaceID, UDPSocket *src, const mDNSAddr *dst, mDNSIPPort dstport);
   2547 
   2548 extern void     mDNSPlatformLock        (const mDNS *const m);
   2549 extern void     mDNSPlatformUnlock      (const mDNS *const m);
   2550 
   2551 extern void     mDNSPlatformStrCopy     (      void *dst, const void *src);
   2552 extern mDNSu32  mDNSPlatformStrLen      (                 const void *src);
   2553 extern void     mDNSPlatformMemCopy     (      void *dst, const void *src, mDNSu32 len);
   2554 extern mDNSBool mDNSPlatformMemSame     (const void *dst, const void *src, mDNSu32 len);
   2555 extern void     mDNSPlatformMemZero     (      void *dst,                  mDNSu32 len);
   2556 #if APPLE_OSX_mDNSResponder && MACOSX_MDNS_MALLOC_DEBUGGING
   2557 #define         mDNSPlatformMemAllocate(X) mallocL(#X, X)
   2558 #else
   2559 extern void *   mDNSPlatformMemAllocate (mDNSu32 len);
   2560 #endif
   2561 extern void     mDNSPlatformMemFree     (void *mem);
   2562 
   2563 // If the platform doesn't have a strong PRNG, we define a naive multiply-and-add based on a seed
   2564 // from the platform layer.  Long-term, we should embed an arc4 implementation, but the strength
   2565 // will still depend on the randomness of the seed.
   2566 #if !defined(_PLATFORM_HAS_STRONG_PRNG_) && (_BUILDING_XCODE_PROJECT_ || defined(_WIN32))
   2567 #define _PLATFORM_HAS_STRONG_PRNG_ 1
   2568 #endif
   2569 #if _PLATFORM_HAS_STRONG_PRNG_
   2570 extern mDNSu32  mDNSPlatformRandomNumber(void);
   2571 #else
   2572 extern mDNSu32  mDNSPlatformRandomSeed  (void);
   2573 #endif // _PLATFORM_HAS_STRONG_PRNG_
   2574 
   2575 extern mStatus  mDNSPlatformTimeInit    (void);
   2576 extern mDNSs32  mDNSPlatformRawTime     (void);
   2577 extern mDNSs32  mDNSPlatformUTC         (void);
   2578 #define mDNS_TimeNow_NoLock(m) (mDNSPlatformRawTime() + (m)->timenow_adjust)
   2579 
   2580 #if MDNS_DEBUGMSGS
   2581 extern void	mDNSPlatformWriteDebugMsg(const char *msg);
   2582 #endif
   2583 extern void	mDNSPlatformWriteLogMsg(const char *ident, const char *msg, mDNSLogLevel_t loglevel);
   2584 
   2585 #if APPLE_OSX_mDNSResponder
   2586 // Utility function for ASL logging
   2587 mDNSexport void mDNSASLLog(uuid_t *uuid, const char *subdomain, const char *result, const char *signature, const char *fmt, ...);
   2588 #endif
   2589 
   2590 // Platform support modules should provide the following functions to map between opaque interface IDs
   2591 // and interface indexes in order to support the DNS-SD API. If your target platform does not support
   2592 // multiple interfaces and/or does not support the DNS-SD API, these functions can be empty.
   2593 extern mDNSInterfaceID mDNSPlatformInterfaceIDfromInterfaceIndex(mDNS *const m, mDNSu32 ifindex);
   2594 extern mDNSu32 mDNSPlatformInterfaceIndexfromInterfaceID(mDNS *const m, mDNSInterfaceID id, mDNSBool suppressNetworkChange);
   2595 
   2596 // Every platform support module must provide the following functions if it is to support unicast DNS
   2597 // and Dynamic Update.
   2598 // All TCP socket operations implemented by the platform layer MUST NOT BLOCK.
   2599 // mDNSPlatformTCPConnect initiates a TCP connection with a peer, adding the socket descriptor to the
   2600 // main event loop.  The return value indicates whether the connection succeeded, failed, or is pending
   2601 // (i.e. the call would block.)  On return, the descriptor parameter is set to point to the connected socket.
   2602 // The TCPConnectionCallback is subsequently invoked when the connection
   2603 // completes (in which case the ConnectionEstablished parameter is true), or data is available for
   2604 // reading on the socket (indicated by the ConnectionEstablished parameter being false.)  If the connection
   2605 // asynchronously fails, the TCPConnectionCallback should be invoked as usual, with the error being
   2606 // returned in subsequent calls to PlatformReadTCP or PlatformWriteTCP.  (This allows for platforms
   2607 // with limited asynchronous error detection capabilities.)  PlatformReadTCP and PlatformWriteTCP must
   2608 // return the number of bytes read/written, 0 if the call would block, and -1 if an error.  PlatformReadTCP
   2609 // should set the closed argument if the socket has been closed.
   2610 // PlatformTCPCloseConnection must close the connection to the peer and remove the descriptor from the
   2611 // event loop.  CloseConnectin may be called at any time, including in a ConnectionCallback.
   2612 
   2613 typedef enum
   2614 	{
   2615 	kTCPSocketFlags_Zero   = 0,
   2616 	kTCPSocketFlags_UseTLS = (1 << 0)
   2617 	} TCPSocketFlags;
   2618 
   2619 typedef void (*TCPConnectionCallback)(TCPSocket *sock, void *context, mDNSBool ConnectionEstablished, mStatus err);
   2620 extern TCPSocket *mDNSPlatformTCPSocket(mDNS *const m, TCPSocketFlags flags, mDNSIPPort *port);	// creates a TCP socket
   2621 extern TCPSocket *mDNSPlatformTCPAccept(TCPSocketFlags flags, int sd);
   2622 extern int        mDNSPlatformTCPGetFD(TCPSocket *sock);
   2623 extern mStatus    mDNSPlatformTCPConnect(TCPSocket *sock, const mDNSAddr *dst, mDNSOpaque16 dstport, domainname *hostname,
   2624 										mDNSInterfaceID InterfaceID, TCPConnectionCallback callback, void *context);
   2625 extern void       mDNSPlatformTCPCloseConnection(TCPSocket *sock);
   2626 extern long       mDNSPlatformReadTCP(TCPSocket *sock, void *buf, unsigned long buflen, mDNSBool *closed);
   2627 extern long       mDNSPlatformWriteTCP(TCPSocket *sock, const char *msg, unsigned long len);
   2628 extern UDPSocket *mDNSPlatformUDPSocket(mDNS *const m, const mDNSIPPort requestedport);
   2629 extern void       mDNSPlatformUDPClose(UDPSocket *sock);
   2630 extern void       mDNSPlatformReceiveBPF_fd(mDNS *const m, int fd);
   2631 extern void       mDNSPlatformUpdateProxyList(mDNS *const m, const mDNSInterfaceID InterfaceID);
   2632 extern void       mDNSPlatformSendRawPacket(const void *const msg, const mDNSu8 *const end, mDNSInterfaceID InterfaceID);
   2633 extern void       mDNSPlatformSetLocalAddressCacheEntry(mDNS *const m, const mDNSAddr *const tpa, const mDNSEthAddr *const tha, mDNSInterfaceID InterfaceID);
   2634 extern void       mDNSPlatformSourceAddrForDest(mDNSAddr *const src, const mDNSAddr *const dst);
   2635 
   2636 // mDNSPlatformTLSSetupCerts/mDNSPlatformTLSTearDownCerts used by dnsextd
   2637 extern mStatus    mDNSPlatformTLSSetupCerts(void);
   2638 extern void       mDNSPlatformTLSTearDownCerts(void);
   2639 
   2640 // Platforms that support unicast browsing and dynamic update registration for clients who do not specify a domain
   2641 // in browse/registration calls must implement these routines to get the "default" browse/registration list.
   2642 
   2643 extern void       mDNSPlatformSetDNSConfig(mDNS *const m, mDNSBool setservers, mDNSBool setsearch, domainname *const fqdn, DNameListElem **RegDomains, DNameListElem **BrowseDomains);
   2644 extern mStatus    mDNSPlatformGetPrimaryInterface(mDNS *const m, mDNSAddr *v4, mDNSAddr *v6, mDNSAddr *router);
   2645 extern void       mDNSPlatformDynDNSHostNameStatusChanged(const domainname *const dname, const mStatus status);
   2646 
   2647 extern void       mDNSPlatformSetAllowSleep(mDNS *const m, mDNSBool allowSleep, const char *reason);
   2648 extern void       mDNSPlatformSendWakeupPacket(mDNS *const m, mDNSInterfaceID InterfaceID, char *EthAddr, char *IPAddr, int iteration);
   2649 extern mDNSBool   mDNSPlatformValidRecordForInterface(AuthRecord *rr, const NetworkInterfaceInfo *intf);
   2650 
   2651 #ifdef _LEGACY_NAT_TRAVERSAL_
   2652 // Support for legacy NAT traversal protocols, implemented by the platform layer and callable by the core.
   2653 extern void     LNT_SendDiscoveryMsg(mDNS *m);
   2654 extern void     LNT_ConfigureRouterInfo(mDNS *m, const mDNSInterfaceID InterfaceID, const mDNSu8 *const data, const mDNSu16 len);
   2655 extern mStatus  LNT_GetExternalAddress(mDNS *m);
   2656 extern mStatus  LNT_MapPort(mDNS *m, NATTraversalInfo *n);
   2657 extern mStatus  LNT_UnmapPort(mDNS *m, NATTraversalInfo *n);
   2658 extern void     LNT_ClearState(mDNS *const m);
   2659 #endif // _LEGACY_NAT_TRAVERSAL_
   2660 
   2661 // The core mDNS code provides these functions, for the platform support code to call at appropriate times
   2662 //
   2663 // mDNS_SetFQDN() is called once on startup (typically from mDNSPlatformInit())
   2664 // and then again on each subsequent change of the host name.
   2665 //
   2666 // mDNS_RegisterInterface() is used by the platform support layer to inform mDNSCore of what
   2667 // physical and/or logical interfaces are available for sending and receiving packets.
   2668 // Typically it is called on startup for each available interface, but register/deregister may be
   2669 // called again later, on multiple occasions, to inform the core of interface configuration changes.
   2670 // If set->Advertise is set non-zero, then mDNS_RegisterInterface() also registers the standard
   2671 // resource records that should be associated with every publicised IP address/interface:
   2672 // -- Name-to-address records (A/AAAA)
   2673 // -- Address-to-name records (PTR)
   2674 // -- Host information (HINFO)
   2675 // IMPORTANT: The specified mDNSInterfaceID MUST NOT be 0, -1, or -2; these values have special meaning
   2676 // mDNS_RegisterInterface does not result in the registration of global hostnames via dynamic update -
   2677 // see mDNS_SetPrimaryInterfaceInfo, mDNS_AddDynDNSHostName, etc. for this purpose.
   2678 // Note that the set may be deallocated immediately after it is deregistered via mDNS_DeegisterInterface.
   2679 //
   2680 // mDNS_RegisterDNS() is used by the platform support layer to provide the core with the addresses of
   2681 // available domain name servers for unicast queries/updates.  RegisterDNS() should be called once for
   2682 // each name server, typically at startup, or when a new name server becomes available.  DeregiterDNS()
   2683 // must be called whenever a registered name server becomes unavailable.  DeregisterDNSList deregisters
   2684 // all registered servers.  mDNS_DNSRegistered() returns true if one or more servers are registered in the core.
   2685 //
   2686 // mDNSCoreInitComplete() is called when the platform support layer is finished.
   2687 // Typically this is at the end of mDNSPlatformInit(), but may be later
   2688 // (on platforms like OT that allow asynchronous initialization of the networking stack).
   2689 //
   2690 // mDNSCoreReceive() is called when a UDP packet is received
   2691 //
   2692 // mDNSCoreMachineSleep() is called when the machine sleeps or wakes
   2693 // (This refers to heavyweight laptop-style sleep/wake that disables network access,
   2694 // not lightweight second-by-second CPU power management modes.)
   2695 
   2696 extern void     mDNS_SetFQDN(mDNS *const m);
   2697 extern void     mDNS_ActivateNetWake_internal  (mDNS *const m, NetworkInterfaceInfo *set);
   2698 extern void     mDNS_DeactivateNetWake_internal(mDNS *const m, NetworkInterfaceInfo *set);
   2699 extern mStatus  mDNS_RegisterInterface  (mDNS *const m, NetworkInterfaceInfo *set, mDNSBool flapping);
   2700 extern void     mDNS_DeregisterInterface(mDNS *const m, NetworkInterfaceInfo *set, mDNSBool flapping);
   2701 extern void     mDNSCoreInitComplete(mDNS *const m, mStatus result);
   2702 extern void     mDNSCoreReceive(mDNS *const m, void *const msg, const mDNSu8 *const end,
   2703 								const mDNSAddr *const srcaddr, const mDNSIPPort srcport,
   2704 								const mDNSAddr *dstaddr, const mDNSIPPort dstport, const mDNSInterfaceID InterfaceID);
   2705 extern void		mDNSCoreRestartQueries(mDNS *const m);
   2706 typedef void    (*FlushCache)(mDNS *const m);
   2707 typedef void    (*CallbackBeforeStartQuery)(mDNS *const m, void *context);
   2708 extern void		mDNSCoreRestartAddressQueries(mDNS *const m, mDNSBool SearchDomainsChanged, FlushCache flushCacheRecords,
   2709 											  CallbackBeforeStartQuery beforeQueryStart, void *context);
   2710 extern mDNSBool mDNSCoreHaveAdvertisedMulticastServices(mDNS *const m);
   2711 extern void     mDNSCoreMachineSleep(mDNS *const m, mDNSBool wake);
   2712 extern mDNSBool mDNSCoreReadyForSleep(mDNS *m, mDNSs32 now);
   2713 extern mDNSs32  mDNSCoreIntervalToNextWake(mDNS *const m, mDNSs32 now);
   2714 
   2715 extern void     mDNSCoreReceiveRawPacket  (mDNS *const m, const mDNSu8 *const p, const mDNSu8 *const end, const mDNSInterfaceID InterfaceID);
   2716 
   2717 extern mDNSBool mDNSAddrIsDNSMulticast(const mDNSAddr *ip);
   2718 
   2719 extern CacheRecord *CreateNewCacheEntry(mDNS *const m, const mDNSu32 slot, CacheGroup *cg, mDNSs32 delay);
   2720 extern void ScheduleNextCacheCheckTime(mDNS *const m, const mDNSu32 slot, const mDNSs32 event);
   2721 extern void GrantCacheExtensions(mDNS *const m, DNSQuestion *q, mDNSu32 lease);
   2722 extern void MakeNegativeCacheRecord(mDNS *const m, CacheRecord *const cr,
   2723 	const domainname *const name, const mDNSu32 namehash, const mDNSu16 rrtype, const mDNSu16 rrclass, mDNSu32 ttl_seconds,
   2724 	mDNSInterfaceID InterfaceID, DNSServer *dnsserver);
   2725 extern void CompleteDeregistration(mDNS *const m, AuthRecord *rr);
   2726 extern void AnswerCurrentQuestionWithResourceRecord(mDNS *const m, CacheRecord *const rr, const QC_result AddRecord);
   2727 extern char *InterfaceNameForID(mDNS *const m, const mDNSInterfaceID InterfaceID);
   2728 extern void DNSServerChangeForQuestion(mDNS *const m, DNSQuestion *q, DNSServer *newServer);
   2729 extern void ActivateUnicastRegistration(mDNS *const m, AuthRecord *const rr);
   2730 extern void CheckSuppressUnusableQuestions(mDNS *const m);
   2731 extern void RetrySearchDomainQuestions(mDNS *const m);
   2732 
   2733 // Used only in logging to restrict the number of /etc/hosts entries printed
   2734 extern void FreeEtcHosts(mDNS *const m, AuthRecord *const rr, mStatus result);
   2735 // exported for using the hash for /etc/hosts AuthRecords
   2736 extern AuthGroup *AuthGroupForName(AuthHash *r, const mDNSu32 slot, const mDNSu32 namehash, const domainname *const name);
   2737 extern AuthGroup *AuthGroupForRecord(AuthHash *r, const mDNSu32 slot, const ResourceRecord *const rr);
   2738 extern AuthGroup *InsertAuthRecord(mDNS *const m, AuthHash *r, AuthRecord *rr);
   2739 extern AuthGroup *RemoveAuthRecord(mDNS *const m, AuthHash *r, AuthRecord *rr);
   2740 
   2741 // For now this AutoTunnel stuff is specific to Mac OS X.
   2742 // In the future, if there's demand, we may see if we can abstract it out cleanly into the platform layer
   2743 #if APPLE_OSX_mDNSResponder
   2744 extern void AutoTunnelCallback(mDNS *const m, DNSQuestion *question, const ResourceRecord *const answer, QC_result AddRecord);
   2745 extern void AddNewClientTunnel(mDNS *const m, DNSQuestion *const q);
   2746 extern void SetupLocalAutoTunnelInterface_internal(mDNS *const m, mDNSBool servicesStarting);
   2747 extern void UpdateAutoTunnelDomainStatuses(const mDNS *const m);
   2748 extern mStatus ActivateLocalProxy(mDNS *const m, char *ifname);
   2749 extern void RemoveAutoTunnel6Record(mDNS *const m);
   2750 extern mDNSBool RecordReadyForSleep(mDNS *const m, AuthRecord *rr);
   2751 #endif
   2752 
   2753 // ***************************************************************************
   2754 #if 0
   2755 #pragma mark -
   2756 #pragma mark - Sleep Proxy
   2757 #endif
   2758 
   2759 // Sleep Proxy Server Property Encoding
   2760 //
   2761 // Sleep Proxy Servers are advertised using a structured service name, consisting of four
   2762 // metrics followed by a human-readable name. The metrics assist clients in deciding which
   2763 // Sleep Proxy Server(s) to use when multiple are available on the network. Each metric
   2764 // is a two-digit decimal number in the range 10-99. Lower metrics are generally better.
   2765 //
   2766 //   AA-BB-CC-DD Name
   2767 //
   2768 // Metrics:
   2769 //
   2770 // AA = Intent
   2771 // BB = Portability
   2772 // CC = Marginal Power
   2773 // DD = Total Power
   2774 //
   2775 //
   2776 // ** Intent Metric **
   2777 //
   2778 // 20 = Dedicated Sleep Proxy Server -- a device, permanently powered on,
   2779 //      installed for the express purpose of providing Sleep Proxy Service.
   2780 //
   2781 // 30 = Primary Network Infrastructure Hardware -- a router, DHCP server, NAT gateway,
   2782 //      or similar permanently installed device which is permanently powered on.
   2783 //      This is hardware designed for the express purpose of being network
   2784 //      infrastructure, and for most home users is typically a single point
   2785 //      of failure for the local network -- e.g. most home users only have
   2786 //      a single NAT gateway / DHCP server. Even though in principle the
   2787 //      hardware might technically be capable of running different software,
   2788 //      a typical user is unlikely to do that. e.g. AirPort base station.
   2789 //
   2790 // 40 = Primary Network Infrastructure Software -- a general-purpose computer
   2791 //      (e.g. Mac, Windows, Linux, etc.) which is currently running DHCP server
   2792 //      or NAT gateway software, but the user could choose to turn that off
   2793 //      fairly easily. e.g. iMac running Internet Sharing
   2794 //
   2795 // 50 = Secondary Network Infrastructure Hardware -- like primary infrastructure
   2796 //      hardware, except not a single point of failure for the entire local network.
   2797 //      For example, an AirPort base station in bridge mode. This may have clients
   2798 //      associated with it, and if it goes away those clients will be inconvenienced,
   2799 //      but unlike the NAT gateway / DHCP server, the entire local network is not
   2800 //      dependent on it.
   2801 //
   2802 // 60 = Secondary Network Infrastructure Software -- like 50, but in a general-
   2803 //      purpose CPU.
   2804 //
   2805 // 70 = Incidentally Available Hardware -- a device which has no power switch
   2806 //      and is generally left powered on all the time. Even though it is not a
   2807 //      part of what we conventionally consider network infrastructure (router,
   2808 //      DHCP, NAT, DNS, etc.), and the rest of the network can operate fine
   2809 //      without it, since it's available and unlikely to be turned off, it is a
   2810 //      reasonable candidate for providing Sleep Proxy Service e.g. Apple TV,
   2811 //      or an AirPort base station in client mode, associated with an existing
   2812 //      wireless network (e.g. AirPort Express connected to a music system, or
   2813 //      being used to share a USB printer).
   2814 //
   2815 // 80 = Incidentally Available Software -- a general-purpose computer which
   2816 //      happens at this time to be set to "never sleep", and as such could be
   2817 //      useful as a Sleep Proxy Server, but has not been intentionally provided
   2818 //      for this purpose. Of all the Intent Metric categories this is the
   2819 //      one most likely to be shut down or put to sleep without warning.
   2820 //      However, if nothing else is availalable, it may be better than nothing.
   2821 //      e.g. Office computer in the workplace which has been set to "never sleep"
   2822 //
   2823 //
   2824 // ** Portability Metric **
   2825 //
   2826 // Inversely related to mass of device, on the basis that, all other things
   2827 // being equal, heavier devices are less likely to be moved than lighter devices.
   2828 // E.g. A MacBook running Internet Sharing is probably more likely to be
   2829 // put to sleep and taken away than a Mac Pro running Internet Sharing.
   2830 // The Portability Metric is a logarithmic decibel scale, computed by taking the
   2831 // (approximate) mass of the device in milligrammes, taking the base 10 logarithm
   2832 // of that, multiplying by 10, and subtracting the result from 100:
   2833 //
   2834 //   Portability Metric = 100 - (log10(mg) * 10)
   2835 //
   2836 // The Portability Metric is not necessarily computed literally from the actual
   2837 // mass of the device; the intent is just that lower numbers indicate more
   2838 // permanent devices, and higher numbers indicate devices more likely to be
   2839 // removed from the network, e.g., in order of increasing portability:
   2840 //
   2841 // Mac Pro < iMac < Laptop < iPhone
   2842 //
   2843 // Example values:
   2844 //
   2845 // 10 = 1 metric tonne
   2846 // 40 = 1kg
   2847 // 70 = 1g
   2848 // 90 = 10mg
   2849 //
   2850 //
   2851 // ** Marginal Power and Total Power Metrics **
   2852 //
   2853 // The Marginal Power Metric is the power difference between sleeping and staying awake
   2854 // to be a Sleep Proxy Server.
   2855 //
   2856 // The Total Power Metric is the total power consumption when being Sleep Proxy Server.
   2857 //
   2858 // The Power Metrics use a logarithmic decibel scale, computed as ten times the
   2859 // base 10 logarithm of the (approximate) power in microwatts:
   2860 //
   2861 //   Power Metric = log10(uW) * 10
   2862 //
   2863 // Higher values indicate higher power consumption. Example values:
   2864 //
   2865 // 10 =  10 uW
   2866 // 20 = 100 uW
   2867 // 30 =   1 mW
   2868 // 60 =   1 W
   2869 // 90 =   1 kW
   2870 
   2871 typedef enum
   2872 	{
   2873 	mDNSSleepProxyMetric_Dedicated          = 20,
   2874 	mDNSSleepProxyMetric_PrimaryHardware    = 30,
   2875 	mDNSSleepProxyMetric_PrimarySoftware    = 40,
   2876 	mDNSSleepProxyMetric_SecondaryHardware  = 50,
   2877 	mDNSSleepProxyMetric_SecondarySoftware  = 60,
   2878 	mDNSSleepProxyMetric_IncidentalHardware = 70,
   2879 	mDNSSleepProxyMetric_IncidentalSoftware = 80
   2880 	} mDNSSleepProxyMetric;
   2881 
   2882 extern void mDNSCoreBeSleepProxyServer_internal(mDNS *const m, mDNSu8 sps, mDNSu8 port, mDNSu8 marginalpower, mDNSu8 totpower);
   2883 #define mDNSCoreBeSleepProxyServer(M,S,P,MP,TP) \
   2884 	do { mDNS_Lock(m); mDNSCoreBeSleepProxyServer_internal((M),(S),(P),(MP),(TP)); mDNS_Unlock(m); } while(0)
   2885 
   2886 extern void FindSPSInCache(mDNS *const m, const DNSQuestion *const q, const CacheRecord *sps[3]);
   2887 #define PrototypeSPSName(X) ((X)[0] >= 11 && (X)[3] == '-' && (X)[ 4] == '9' && (X)[ 5] == '9' && \
   2888                                              (X)[6] == '-' && (X)[ 7] == '9' && (X)[ 8] == '9' && \
   2889                                              (X)[9] == '-' && (X)[10] == '9' && (X)[11] == '9'    )
   2890 #define ValidSPSName(X) ((X)[0] >= 5 && mDNSIsDigit((X)[1]) && mDNSIsDigit((X)[2]) && mDNSIsDigit((X)[4]) && mDNSIsDigit((X)[5]))
   2891 #define SPSMetric(X) (!ValidSPSName(X) || PrototypeSPSName(X) ? 1000000 : \
   2892 	((X)[1]-'0') * 100000 + ((X)[2]-'0') * 10000 + ((X)[4]-'0') * 1000 + ((X)[5]-'0') * 100 + ((X)[7]-'0') * 10 + ((X)[8]-'0'))
   2893 
   2894 // ***************************************************************************
   2895 #if 0
   2896 #pragma mark -
   2897 #pragma mark - Compile-Time assertion checks
   2898 #endif
   2899 
   2900 // Some C compiler cleverness. We can make the compiler check certain things for
   2901 // us, and report compile-time errors if anything is wrong. The usual way to do
   2902 // this would be to use a run-time "if" statement, but then you don't find out
   2903 // what's wrong until you run the software. This way, if the assertion condition
   2904 // is false, the array size is negative, and the complier complains immediately.
   2905 
   2906 struct CompileTimeAssertionChecks_mDNS
   2907 	{
   2908 	// Check that the compiler generated our on-the-wire packet format structure definitions
   2909 	// properly packed, without adding padding bytes to align fields on 32-bit or 64-bit boundaries.
   2910 	char assert0[(sizeof(rdataSRV)         == 262                          ) ? 1 : -1];
   2911 	char assert1[(sizeof(DNSMessageHeader) ==  12                          ) ? 1 : -1];
   2912 	char assert2[(sizeof(DNSMessage)       ==  12+AbsoluteMaxDNSMessageData) ? 1 : -1];
   2913 	char assert3[(sizeof(mDNSs8)           ==   1                          ) ? 1 : -1];
   2914 	char assert4[(sizeof(mDNSu8)           ==   1                          ) ? 1 : -1];
   2915 	char assert5[(sizeof(mDNSs16)          ==   2                          ) ? 1 : -1];
   2916 	char assert6[(sizeof(mDNSu16)          ==   2                          ) ? 1 : -1];
   2917 	char assert7[(sizeof(mDNSs32)          ==   4                          ) ? 1 : -1];
   2918 	char assert8[(sizeof(mDNSu32)          ==   4                          ) ? 1 : -1];
   2919 	char assert9[(sizeof(mDNSOpaque16)     ==   2                          ) ? 1 : -1];
   2920 	char assertA[(sizeof(mDNSOpaque32)     ==   4                          ) ? 1 : -1];
   2921 	char assertB[(sizeof(mDNSOpaque128)    ==  16                          ) ? 1 : -1];
   2922 	char assertC[(sizeof(CacheRecord  )    ==  sizeof(CacheGroup)          ) ? 1 : -1];
   2923 	char assertD[(sizeof(int)              >=  4                           ) ? 1 : -1];
   2924 	char assertE[(StandardAuthRDSize       >=  256                         ) ? 1 : -1];
   2925 	char assertF[(sizeof(EthernetHeader)   ==   14                         ) ? 1 : -1];
   2926 	char assertG[(sizeof(ARP_EthIP     )   ==   28                         ) ? 1 : -1];
   2927 	char assertH[(sizeof(IPv4Header    )   ==   20                         ) ? 1 : -1];
   2928 	char assertI[(sizeof(IPv6Header    )   ==   40                         ) ? 1 : -1];
   2929 	char assertJ[(sizeof(IPv6NDP       )   ==   24                         ) ? 1 : -1];
   2930 	char assertK[(sizeof(UDPHeader     )   ==    8                         ) ? 1 : -1];
   2931 	char assertL[(sizeof(IKEHeader     )   ==   28                         ) ? 1 : -1];
   2932 	char assertM[(sizeof(TCPHeader     )   ==   20                         ) ? 1 : -1];
   2933 
   2934 	// Check our structures are reasonable sizes. Including overly-large buffers, or embedding
   2935 	// other overly-large structures instead of having a pointer to them, can inadvertently
   2936 	// cause structure sizes (and therefore memory usage) to balloon unreasonably.
   2937 	char sizecheck_RDataBody           [(sizeof(RDataBody)            ==   264) ? 1 : -1];
   2938 	char sizecheck_ResourceRecord      [(sizeof(ResourceRecord)       <=    64) ? 1 : -1];
   2939 	char sizecheck_AuthRecord          [(sizeof(AuthRecord)           <=  1208) ? 1 : -1];
   2940 	char sizecheck_CacheRecord         [(sizeof(CacheRecord)          <=   184) ? 1 : -1];
   2941 	char sizecheck_CacheGroup          [(sizeof(CacheGroup)           <=   184) ? 1 : -1];
   2942 	char sizecheck_DNSQuestion         [(sizeof(DNSQuestion)          <=   786) ? 1 : -1];
   2943 	char sizecheck_ZoneData            [(sizeof(ZoneData)             <=  1624) ? 1 : -1];
   2944 	char sizecheck_NATTraversalInfo    [(sizeof(NATTraversalInfo)     <=   192) ? 1 : -1];
   2945 	char sizecheck_HostnameInfo        [(sizeof(HostnameInfo)         <=  3050) ? 1 : -1];
   2946 	char sizecheck_DNSServer           [(sizeof(DNSServer)            <=   320) ? 1 : -1];
   2947 	char sizecheck_NetworkInterfaceInfo[(sizeof(NetworkInterfaceInfo) <=  6850) ? 1 : -1];
   2948 	char sizecheck_ServiceRecordSet    [(sizeof(ServiceRecordSet)     <=  5500) ? 1 : -1];
   2949 	char sizecheck_DomainAuthInfo      [(sizeof(DomainAuthInfo)       <=  7808) ? 1 : -1];
   2950 	char sizecheck_ServiceInfoQuery    [(sizeof(ServiceInfoQuery)     <=  3200) ? 1 : -1];
   2951 #if APPLE_OSX_mDNSResponder
   2952 	char sizecheck_ClientTunnel        [(sizeof(ClientTunnel)         <=  1148) ? 1 : -1];
   2953 #endif
   2954 	};
   2955 
   2956 // ***************************************************************************
   2957 
   2958 #ifdef __cplusplus
   2959 	}
   2960 #endif
   2961 
   2962 #endif
   2963