#ifdef _WIN32
#define _CRT_SECURE_NO_WARNINGS 1
#endif

#include <stdio.h>

#include <errno.h>
#include <signal.h>

#ifdef _WIN32
#include <winsock2.h>
#include <iphlpapi.h>
#define sleep(x) Sleep(x * 1000)
#else
#include <netdb.h>
#include <ifaddrs.h>
#include <net/if.h>
#include <sys/time.h>
#endif

// Alias some things to simulate recieving data to fuzz library
#if defined(MDNS_FUZZING)
#define recvfrom(sock, buffer, capacity, flags, src_addr, addrlen) ((mdns_ssize_t)capacity)
#define printf
#endif

#include "mdns.h"

#if defined(MDNS_FUZZING)
#undef recvfrom
#endif

static char addrbuffer[64];
static char entrybuffer[256];
static char namebuffer[256];
static char sendbuffer[1024];
static mdns_record_txt_t txtbuffer[128];

static struct sockaddr_in service_address_ipv4;
static struct sockaddr_in6 service_address_ipv6;

static int has_ipv4;
static int has_ipv6;

volatile sig_atomic_t running = 1;

// Data for our service including the mDNS records
typedef struct {
	mdns_string_t service;
	mdns_string_t hostname;
	mdns_string_t service_instance;
	mdns_string_t hostname_qualified;
	struct sockaddr_in address_ipv4;
	struct sockaddr_in6 address_ipv6;
	int port;
	mdns_record_t record_ptr;
	mdns_record_t record_srv;
	mdns_record_t record_a;
	mdns_record_t record_aaaa;
	mdns_record_t txt_record[2];
} service_t;

static mdns_string_t
ipv4_address_to_string(char* buffer, size_t capacity, const struct sockaddr_in* addr,
                       size_t addrlen) {
	char host[NI_MAXHOST] = {0};
	char service[NI_MAXSERV] = {0};
	int ret = getnameinfo((const struct sockaddr*)addr, (socklen_t)addrlen, host, NI_MAXHOST,
	                      service, NI_MAXSERV, NI_NUMERICSERV | NI_NUMERICHOST);
	int len = 0;
	if (ret == 0) {
		if (addr->sin_port != 0)
			len = snprintf(buffer, capacity, "%s:%s", host, service);
		else
			len = snprintf(buffer, capacity, "%s", host);
	}
	if (len >= (int)capacity)
		len = (int)capacity - 1;
	mdns_string_t str;
	str.str = buffer;
	str.length = len;
	return str;
}

static mdns_string_t
ipv6_address_to_string(char* buffer, size_t capacity, const struct sockaddr_in6* addr,
                       size_t addrlen) {
	char host[NI_MAXHOST] = {0};
	char service[NI_MAXSERV] = {0};
	int ret = getnameinfo((const struct sockaddr*)addr, (socklen_t)addrlen, host, NI_MAXHOST,
	                      service, NI_MAXSERV, NI_NUMERICSERV | NI_NUMERICHOST);
	int len = 0;
	if (ret == 0) {
		if (addr->sin6_port != 0)
			len = snprintf(buffer, capacity, "[%s]:%s", host, service);
		else
			len = snprintf(buffer, capacity, "%s", host);
	}
	if (len >= (int)capacity)
		len = (int)capacity - 1;
	mdns_string_t str;
	str.str = buffer;
	str.length = len;
	return str;
}

static mdns_string_t
ip_address_to_string(char* buffer, size_t capacity, const struct sockaddr* addr, size_t addrlen) {
	if (addr->sa_family == AF_INET6)
		return ipv6_address_to_string(buffer, capacity, (const struct sockaddr_in6*)addr, addrlen);
	return ipv4_address_to_string(buffer, capacity, (const struct sockaddr_in*)addr, addrlen);
}

// Callback handling parsing answers to queries sent
static int
query_callback(int sock, const struct sockaddr* from, size_t addrlen, mdns_entry_type_t entry,
               uint16_t query_id, uint16_t rtype, uint16_t rclass, uint32_t ttl, const void* data,
               size_t size, size_t name_offset, size_t name_length, size_t record_offset,
               size_t record_length, void* user_data) {
	(void)sizeof(sock);
	(void)sizeof(query_id);
	(void)sizeof(name_length);
	(void)sizeof(user_data);
	mdns_string_t fromaddrstr = ip_address_to_string(addrbuffer, sizeof(addrbuffer), from, addrlen);
	const char* entrytype = (entry == MDNS_ENTRYTYPE_ANSWER) ?
                                "answer" :
                                ((entry == MDNS_ENTRYTYPE_AUTHORITY) ? "authority" : "additional");
	mdns_string_t entrystr =
	    mdns_string_extract(data, size, &name_offset, entrybuffer, sizeof(entrybuffer));
	if (rtype == MDNS_RECORDTYPE_PTR) {
		mdns_string_t namestr = mdns_record_parse_ptr(data, size, record_offset, record_length,
		                                              namebuffer, sizeof(namebuffer));
		printf("%.*s : %s %.*s PTR %.*s rclass 0x%x ttl %u length %d\n",
		       MDNS_STRING_FORMAT(fromaddrstr), entrytype, MDNS_STRING_FORMAT(entrystr),
		       MDNS_STRING_FORMAT(namestr), rclass, ttl, (int)record_length);
	} else if (rtype == MDNS_RECORDTYPE_SRV) {
		mdns_record_srv_t srv = mdns_record_parse_srv(data, size, record_offset, record_length,
		                                              namebuffer, sizeof(namebuffer));
		printf("%.*s : %s %.*s SRV %.*s priority %d weight %d port %d\n",
		       MDNS_STRING_FORMAT(fromaddrstr), entrytype, MDNS_STRING_FORMAT(entrystr),
		       MDNS_STRING_FORMAT(srv.name), srv.priority, srv.weight, srv.port);
	} else if (rtype == MDNS_RECORDTYPE_A) {
		struct sockaddr_in addr;
		mdns_record_parse_a(data, size, record_offset, record_length, &addr);
		mdns_string_t addrstr =
		    ipv4_address_to_string(namebuffer, sizeof(namebuffer), &addr, sizeof(addr));
		printf("%.*s : %s %.*s A %.*s\n", MDNS_STRING_FORMAT(fromaddrstr), entrytype,
		       MDNS_STRING_FORMAT(entrystr), MDNS_STRING_FORMAT(addrstr));
	} else if (rtype == MDNS_RECORDTYPE_AAAA) {
		struct sockaddr_in6 addr;
		mdns_record_parse_aaaa(data, size, record_offset, record_length, &addr);
		mdns_string_t addrstr =
		    ipv6_address_to_string(namebuffer, sizeof(namebuffer), &addr, sizeof(addr));
		printf("%.*s : %s %.*s AAAA %.*s\n", MDNS_STRING_FORMAT(fromaddrstr), entrytype,
		       MDNS_STRING_FORMAT(entrystr), MDNS_STRING_FORMAT(addrstr));
	} else if (rtype == MDNS_RECORDTYPE_TXT) {
		size_t parsed = mdns_record_parse_txt(data, size, record_offset, record_length, txtbuffer,
		                                      sizeof(txtbuffer) / sizeof(mdns_record_txt_t));
		for (size_t itxt = 0; itxt < parsed; ++itxt) {
			if (txtbuffer[itxt].value.length) {
				printf("%.*s : %s %.*s TXT %.*s = %.*s\n", MDNS_STRING_FORMAT(fromaddrstr),
				       entrytype, MDNS_STRING_FORMAT(entrystr),
				       MDNS_STRING_FORMAT(txtbuffer[itxt].key),
				       MDNS_STRING_FORMAT(txtbuffer[itxt].value));
			} else {
				printf("%.*s : %s %.*s TXT %.*s\n", MDNS_STRING_FORMAT(fromaddrstr), entrytype,
				       MDNS_STRING_FORMAT(entrystr), MDNS_STRING_FORMAT(txtbuffer[itxt].key));
			}
		}
	} else {
		printf("%.*s : %s %.*s type %u rclass 0x%x ttl %u length %d\n",
		       MDNS_STRING_FORMAT(fromaddrstr), entrytype, MDNS_STRING_FORMAT(entrystr), rtype,
		       rclass, ttl, (int)record_length);
	}
	return 0;
}

// Callback handling questions incoming on service sockets
static int
service_callback(int sock, const struct sockaddr* from, size_t addrlen, mdns_entry_type_t entry,
                 uint16_t query_id, uint16_t rtype, uint16_t rclass, uint32_t ttl, const void* data,
                 size_t size, size_t name_offset, size_t name_length, size_t record_offset,
                 size_t record_length, void* user_data) {
	(void)sizeof(ttl);
	if (entry != MDNS_ENTRYTYPE_QUESTION)
		return 0;

	const char dns_sd[] = "_services._dns-sd._udp.local.";
	const service_t* service = (const service_t*)user_data;

	mdns_string_t fromaddrstr = ip_address_to_string(addrbuffer, sizeof(addrbuffer), from, addrlen);

	size_t offset = name_offset;
	mdns_string_t name = mdns_string_extract(data, size, &offset, namebuffer, sizeof(namebuffer));

	const char* record_name = 0;
	if (rtype == MDNS_RECORDTYPE_PTR)
		record_name = "PTR";
	else if (rtype == MDNS_RECORDTYPE_SRV)
		record_name = "SRV";
	else if (rtype == MDNS_RECORDTYPE_A)
		record_name = "A";
	else if (rtype == MDNS_RECORDTYPE_AAAA)
		record_name = "AAAA";
	else if (rtype == MDNS_RECORDTYPE_TXT)
		record_name = "TXT";
	else if (rtype == MDNS_RECORDTYPE_ANY)
		record_name = "ANY";
	else
		return 0;
	printf("Query %s %.*s\n", record_name, MDNS_STRING_FORMAT(name));

	if ((name.length == (sizeof(dns_sd) - 1)) &&
	    (strncmp(name.str, dns_sd, sizeof(dns_sd) - 1) == 0)) {
		if ((rtype == MDNS_RECORDTYPE_PTR) || (rtype == MDNS_RECORDTYPE_ANY)) {
			// The PTR query was for the DNS-SD domain, send answer with a PTR record for the
			// service name we advertise, typically on the "<_service-name>._tcp.local." format

			// Answer PTR record reverse mapping "<_service-name>._tcp.local." to
			// "<hostname>.<_service-name>._tcp.local."
			mdns_record_t answer = {
			    .name = name, .type = MDNS_RECORDTYPE_PTR, .data.ptr.name = service->service};

			// Send the answer, unicast or multicast depending on flag in query
			uint16_t unicast = (rclass & MDNS_UNICAST_RESPONSE);
			printf("  --> answer %.*s (%s)\n", MDNS_STRING_FORMAT(answer.data.ptr.name),
			       (unicast ? "unicast" : "multicast"));

			if (unicast) {
				mdns_query_answer_unicast(sock, from, addrlen, sendbuffer, sizeof(sendbuffer),
				                          query_id, rtype, name.str, name.length, answer, 0, 0, 0,
				                          0);
			} else {
				mdns_query_answer_multicast(sock, sendbuffer, sizeof(sendbuffer), answer, 0, 0, 0,
				                            0);
			}
		}
	} else if ((name.length == service->service.length) &&
	           (strncmp(name.str, service->service.str, name.length) == 0)) {
		if ((rtype == MDNS_RECORDTYPE_PTR) || (rtype == MDNS_RECORDTYPE_ANY)) {
			// The PTR query was for our service (usually "<_service-name._tcp.local"), answer a PTR
			// record reverse mapping the queried service name to our service instance name
			// (typically on the "<hostname>.<_service-name>._tcp.local." format), and add
			// additional records containing the SRV record mapping the service instance name to our
			// qualified hostname (typically "<hostname>.local.") and port, as well as any IPv4/IPv6
			// address for the hostname as A/AAAA records, and two test TXT records

			// Answer PTR record reverse mapping "<_service-name>._tcp.local." to
			// "<hostname>.<_service-name>._tcp.local."
			mdns_record_t answer = service->record_ptr;

			mdns_record_t additional[5] = {0};
			size_t additional_count = 0;

			// SRV record mapping "<hostname>.<_service-name>._tcp.local." to
			// "<hostname>.local." with port. Set weight & priority to 0.
			additional[additional_count++] = service->record_srv;

			// A/AAAA records mapping "<hostname>.local." to IPv4/IPv6 addresses
			if (service->address_ipv4.sin_family == AF_INET)
				additional[additional_count++] = service->record_a;
			if (service->address_ipv6.sin6_family == AF_INET6)
				additional[additional_count++] = service->record_aaaa;

			// Add two test TXT records for our service instance name, will be coalesced into
			// one record with both key-value pair strings by the library
			additional[additional_count++] = service->txt_record[0];
			additional[additional_count++] = service->txt_record[1];

			// Send the answer, unicast or multicast depending on flag in query
			uint16_t unicast = (rclass & MDNS_UNICAST_RESPONSE);
			printf("  --> answer %.*s (%s)\n",
			       MDNS_STRING_FORMAT(service->record_ptr.data.ptr.name),
			       (unicast ? "unicast" : "multicast"));

			if (unicast) {
				mdns_query_answer_unicast(sock, from, addrlen, sendbuffer, sizeof(sendbuffer),
				                          query_id, rtype, name.str, name.length, answer, 0, 0,
				                          additional, additional_count);
			} else {
				mdns_query_answer_multicast(sock, sendbuffer, sizeof(sendbuffer), answer, 0, 0,
				                            additional, additional_count);
			}
		}
	} else if ((name.length == service->service_instance.length) &&
	           (strncmp(name.str, service->service_instance.str, name.length) == 0)) {
		if ((rtype == MDNS_RECORDTYPE_SRV) || (rtype == MDNS_RECORDTYPE_ANY)) {
			// The SRV query was for our service instance (usually
			// "<hostname>.<_service-name._tcp.local"), answer a SRV record mapping the service
			// instance name to our qualified hostname (typically "<hostname>.local.") and port, as
			// well as any IPv4/IPv6 address for the hostname as A/AAAA records, and two test TXT
			// records

			// Answer PTR record reverse mapping "<_service-name>._tcp.local." to
			// "<hostname>.<_service-name>._tcp.local."
			mdns_record_t answer = service->record_srv;

			mdns_record_t additional[5] = {0};
			size_t additional_count = 0;

			// A/AAAA records mapping "<hostname>.local." to IPv4/IPv6 addresses
			if (service->address_ipv4.sin_family == AF_INET)
				additional[additional_count++] = service->record_a;
			if (service->address_ipv6.sin6_family == AF_INET6)
				additional[additional_count++] = service->record_aaaa;

			// Add two test TXT records for our service instance name, will be coalesced into
			// one record with both key-value pair strings by the library
			additional[additional_count++] = service->txt_record[0];
			additional[additional_count++] = service->txt_record[1];

			// Send the answer, unicast or multicast depending on flag in query
			uint16_t unicast = (rclass & MDNS_UNICAST_RESPONSE);
			printf("  --> answer %.*s port %d (%s)\n",
			       MDNS_STRING_FORMAT(service->record_srv.data.srv.name), service->port,
			       (unicast ? "unicast" : "multicast"));

			if (unicast) {
				mdns_query_answer_unicast(sock, from, addrlen, sendbuffer, sizeof(sendbuffer),
				                          query_id, rtype, name.str, name.length, answer, 0, 0,
				                          additional, additional_count);
			} else {
				mdns_query_answer_multicast(sock, sendbuffer, sizeof(sendbuffer), answer, 0, 0,
				                            additional, additional_count);
			}
		}
	} else if ((name.length == service->hostname_qualified.length) &&
	           (strncmp(name.str, service->hostname_qualified.str, name.length) == 0)) {
		if (((rtype == MDNS_RECORDTYPE_A) || (rtype == MDNS_RECORDTYPE_ANY)) &&
		    (service->address_ipv4.sin_family == AF_INET)) {
			// The A query was for our qualified hostname (typically "<hostname>.local.") and we
			// have an IPv4 address, answer with an A record mappiing the hostname to an IPv4
			// address, as well as any IPv6 address for the hostname, and two test TXT records

			// Answer A records mapping "<hostname>.local." to IPv4 address
			mdns_record_t answer = service->record_a;

			mdns_record_t additional[5] = {0};
			size_t additional_count = 0;

			// AAAA record mapping "<hostname>.local." to IPv6 addresses
			if (service->address_ipv6.sin6_family == AF_INET6)
				additional[additional_count++] = service->record_aaaa;

			// Add two test TXT records for our service instance name, will be coalesced into
			// one record with both key-value pair strings by the library
			additional[additional_count++] = service->txt_record[0];
			additional[additional_count++] = service->txt_record[1];

			// Send the answer, unicast or multicast depending on flag in query
			uint16_t unicast = (rclass & MDNS_UNICAST_RESPONSE);
			mdns_string_t addrstr = ip_address_to_string(
			    addrbuffer, sizeof(addrbuffer), (struct sockaddr*)&service->record_a.data.a.addr,
			    sizeof(service->record_a.data.a.addr));
			printf("  --> answer %.*s IPv4 %.*s (%s)\n", MDNS_STRING_FORMAT(service->record_a.name),
			       MDNS_STRING_FORMAT(addrstr), (unicast ? "unicast" : "multicast"));

			if (unicast) {
				mdns_query_answer_unicast(sock, from, addrlen, sendbuffer, sizeof(sendbuffer),
				                          query_id, rtype, name.str, name.length, answer, 0, 0,
				                          additional, additional_count);
			} else {
				mdns_query_answer_multicast(sock, sendbuffer, sizeof(sendbuffer), answer, 0, 0,
				                            additional, additional_count);
			}
		} else if (((rtype == MDNS_RECORDTYPE_AAAA) || (rtype == MDNS_RECORDTYPE_ANY)) &&
		           (service->address_ipv6.sin6_family == AF_INET6)) {
			// The AAAA query was for our qualified hostname (typically "<hostname>.local.") and we
			// have an IPv6 address, answer with an AAAA record mappiing the hostname to an IPv6
			// address, as well as any IPv4 address for the hostname, and two test TXT records

			// Answer AAAA records mapping "<hostname>.local." to IPv6 address
			mdns_record_t answer = service->record_aaaa;

			mdns_record_t additional[5] = {0};
			size_t additional_count = 0;

			// A record mapping "<hostname>.local." to IPv4 addresses
			if (service->address_ipv4.sin_family == AF_INET)
				additional[additional_count++] = service->record_a;

			// Add two test TXT records for our service instance name, will be coalesced into
			// one record with both key-value pair strings by the library
			additional[additional_count++] = service->txt_record[0];
			additional[additional_count++] = service->txt_record[1];

			// Send the answer, unicast or multicast depending on flag in query
			uint16_t unicast = (rclass & MDNS_UNICAST_RESPONSE);
			mdns_string_t addrstr =
			    ip_address_to_string(addrbuffer, sizeof(addrbuffer),
			                         (struct sockaddr*)&service->record_aaaa.data.aaaa.addr,
			                         sizeof(service->record_aaaa.data.aaaa.addr));
			printf("  --> answer %.*s IPv6 %.*s (%s)\n",
			       MDNS_STRING_FORMAT(service->record_aaaa.name), MDNS_STRING_FORMAT(addrstr),
			       (unicast ? "unicast" : "multicast"));

			if (unicast) {
				mdns_query_answer_unicast(sock, from, addrlen, sendbuffer, sizeof(sendbuffer),
				                          query_id, rtype, name.str, name.length, answer, 0, 0,
				                          additional, additional_count);
			} else {
				mdns_query_answer_multicast(sock, sendbuffer, sizeof(sendbuffer), answer, 0, 0,
				                            additional, additional_count);
			}
		}
	}
	return 0;
}

// Callback handling questions and answers dump
static int
dump_callback(int sock, const struct sockaddr* from, size_t addrlen, mdns_entry_type_t entry,
              uint16_t query_id, uint16_t rtype, uint16_t rclass, uint32_t ttl, const void* data,
              size_t size, size_t name_offset, size_t name_length, size_t record_offset,
              size_t record_length, void* user_data) {
	mdns_string_t fromaddrstr = ip_address_to_string(addrbuffer, sizeof(addrbuffer), from, addrlen);

	size_t offset = name_offset;
	mdns_string_t name = mdns_string_extract(data, size, &offset, namebuffer, sizeof(namebuffer));

	const char* record_name = 0;
	if (rtype == MDNS_RECORDTYPE_PTR)
		record_name = "PTR";
	else if (rtype == MDNS_RECORDTYPE_SRV)
		record_name = "SRV";
	else if (rtype == MDNS_RECORDTYPE_A)
		record_name = "A";
	else if (rtype == MDNS_RECORDTYPE_AAAA)
		record_name = "AAAA";
	else if (rtype == MDNS_RECORDTYPE_TXT)
		record_name = "TXT";
	else if (rtype == MDNS_RECORDTYPE_ANY)
		record_name = "ANY";
	else
		record_name = "<UNKNOWN>";

	const char* entry_type = "Question";
	if (entry == MDNS_ENTRYTYPE_ANSWER)
		entry_type = "Answer";
	else if (entry == MDNS_ENTRYTYPE_AUTHORITY)
		entry_type = "Authority";
	else if (entry == MDNS_ENTRYTYPE_ADDITIONAL)
		entry_type = "Additional";

	printf("%.*s: %s %s %.*s rclass 0x%x ttl %u\n", MDNS_STRING_FORMAT(fromaddrstr), entry_type,
	       record_name, MDNS_STRING_FORMAT(name), (unsigned int)rclass, ttl);

	return 0;
}

// Open sockets for sending one-shot multicast queries from an ephemeral port
static int
open_client_sockets(int* sockets, int max_sockets, int port) {
	// When sending, each socket can only send to one network interface
	// Thus we need to open one socket for each interface and address family
	int num_sockets = 0;

#ifdef _WIN32

	IP_ADAPTER_ADDRESSES* adapter_address = 0;
	ULONG address_size = 8000;
	unsigned int ret;
	unsigned int num_retries = 4;
	do {
		adapter_address = (IP_ADAPTER_ADDRESSES*)malloc(address_size);
		ret = GetAdaptersAddresses(AF_UNSPEC, GAA_FLAG_SKIP_MULTICAST | GAA_FLAG_SKIP_ANYCAST, 0,
		                           adapter_address, &address_size);
		if (ret == ERROR_BUFFER_OVERFLOW) {
			free(adapter_address);
			adapter_address = 0;
			address_size *= 2;
		} else {
			break;
		}
	} while (num_retries-- > 0);

	if (!adapter_address || (ret != NO_ERROR)) {
		free(adapter_address);
		printf("Failed to get network adapter addresses\n");
		return num_sockets;
	}

	int first_ipv4 = 1;
	int first_ipv6 = 1;
	for (PIP_ADAPTER_ADDRESSES adapter = adapter_address; adapter; adapter = adapter->Next) {
		if (adapter->TunnelType == TUNNEL_TYPE_TEREDO)
			continue;
		if (adapter->OperStatus != IfOperStatusUp)
			continue;

		for (IP_ADAPTER_UNICAST_ADDRESS* unicast = adapter->FirstUnicastAddress; unicast;
		     unicast = unicast->Next) {
			if (unicast->Address.lpSockaddr->sa_family == AF_INET) {
				struct sockaddr_in* saddr = (struct sockaddr_in*)unicast->Address.lpSockaddr;
				if ((saddr->sin_addr.S_un.S_un_b.s_b1 != 127) ||
				    (saddr->sin_addr.S_un.S_un_b.s_b2 != 0) ||
				    (saddr->sin_addr.S_un.S_un_b.s_b3 != 0) ||
				    (saddr->sin_addr.S_un.S_un_b.s_b4 != 1)) {
					int log_addr = 0;
					if (first_ipv4) {
						service_address_ipv4 = *saddr;
						first_ipv4 = 0;
						log_addr = 1;
					}
					has_ipv4 = 1;
					if (num_sockets < max_sockets) {
						saddr->sin_port = htons((unsigned short)port);
						int sock = mdns_socket_open_ipv4(saddr);
						if (sock >= 0) {
							sockets[num_sockets++] = sock;
							log_addr = 1;
						} else {
							log_addr = 0;
						}
					}
					if (log_addr) {
						char buffer[128];
						mdns_string_t addr = ipv4_address_to_string(buffer, sizeof(buffer), saddr,
						                                            sizeof(struct sockaddr_in));
						printf("Local IPv4 address: %.*s\n", MDNS_STRING_FORMAT(addr));
					}
				}
			} else if (unicast->Address.lpSockaddr->sa_family == AF_INET6) {
				struct sockaddr_in6* saddr = (struct sockaddr_in6*)unicast->Address.lpSockaddr;
				// Ignore link-local addresses
				if (saddr->sin6_scope_id)
					continue;
				static const unsigned char localhost[] = {0, 0, 0, 0, 0, 0, 0, 0,
				                                          0, 0, 0, 0, 0, 0, 0, 1};
				static const unsigned char localhost_mapped[] = {0, 0, 0,    0,    0,    0, 0, 0,
				                                                 0, 0, 0xff, 0xff, 0x7f, 0, 0, 1};
				if ((unicast->DadState == NldsPreferred) &&
				    memcmp(saddr->sin6_addr.s6_addr, localhost, 16) &&
				    memcmp(saddr->sin6_addr.s6_addr, localhost_mapped, 16)) {
					int log_addr = 0;
					if (first_ipv6) {
						service_address_ipv6 = *saddr;
						first_ipv6 = 0;
						log_addr = 1;
					}
					has_ipv6 = 1;
					if (num_sockets < max_sockets) {
						saddr->sin6_port = htons((unsigned short)port);
						int sock = mdns_socket_open_ipv6(saddr);
						if (sock >= 0) {
							sockets[num_sockets++] = sock;
							log_addr = 1;
						} else {
							log_addr = 0;
						}
					}
					if (log_addr) {
						char buffer[128];
						mdns_string_t addr = ipv6_address_to_string(buffer, sizeof(buffer), saddr,
						                                            sizeof(struct sockaddr_in6));
						printf("Local IPv6 address: %.*s\n", MDNS_STRING_FORMAT(addr));
					}
				}
			}
		}
	}

	free(adapter_address);

#else

	struct ifaddrs* ifaddr = 0;
	struct ifaddrs* ifa = 0;

	if (getifaddrs(&ifaddr) < 0)
		printf("Unable to get interface addresses\n");

	int first_ipv4 = 1;
	int first_ipv6 = 1;
	for (ifa = ifaddr; ifa; ifa = ifa->ifa_next) {
		if (!ifa->ifa_addr)
			continue;
		if (!(ifa->ifa_flags & IFF_UP) || !(ifa->ifa_flags & IFF_MULTICAST))
			continue;
		if ((ifa->ifa_flags & IFF_LOOPBACK) || (ifa->ifa_flags & IFF_POINTOPOINT))
			continue;

		if (ifa->ifa_addr->sa_family == AF_INET) {
			struct sockaddr_in* saddr = (struct sockaddr_in*)ifa->ifa_addr;
			if (saddr->sin_addr.s_addr != htonl(INADDR_LOOPBACK)) {
				int log_addr = 0;
				if (first_ipv4) {
					service_address_ipv4 = *saddr;
					first_ipv4 = 0;
					log_addr = 1;
				}
				has_ipv4 = 1;
				if (num_sockets < max_sockets) {
					saddr->sin_port = htons(port);
					int sock = mdns_socket_open_ipv4(saddr);
					if (sock >= 0) {
						sockets[num_sockets++] = sock;
						log_addr = 1;
					} else {
						log_addr = 0;
					}
				}
				if (log_addr) {
					char buffer[128];
					mdns_string_t addr = ipv4_address_to_string(buffer, sizeof(buffer), saddr,
					                                            sizeof(struct sockaddr_in));
					printf("Local IPv4 address: %.*s\n", MDNS_STRING_FORMAT(addr));
				}
			}
		} else if (ifa->ifa_addr->sa_family == AF_INET6) {
			struct sockaddr_in6* saddr = (struct sockaddr_in6*)ifa->ifa_addr;
			// Ignore link-local addresses
			if (saddr->sin6_scope_id)
				continue;
			static const unsigned char localhost[] = {0, 0, 0, 0, 0, 0, 0, 0,
			                                          0, 0, 0, 0, 0, 0, 0, 1};
			static const unsigned char localhost_mapped[] = {0, 0, 0,    0,    0,    0, 0, 0,
			                                                 0, 0, 0xff, 0xff, 0x7f, 0, 0, 1};
			if (memcmp(saddr->sin6_addr.s6_addr, localhost, 16) &&
			    memcmp(saddr->sin6_addr.s6_addr, localhost_mapped, 16)) {
				int log_addr = 0;
				if (first_ipv6) {
					service_address_ipv6 = *saddr;
					first_ipv6 = 0;
					log_addr = 1;
				}
				has_ipv6 = 1;
				if (num_sockets < max_sockets) {
					saddr->sin6_port = htons(port);
					int sock = mdns_socket_open_ipv6(saddr);
					if (sock >= 0) {
						sockets[num_sockets++] = sock;
						log_addr = 1;
					} else {
						log_addr = 0;
					}
				}
				if (log_addr) {
					char buffer[128];
					mdns_string_t addr = ipv6_address_to_string(buffer, sizeof(buffer), saddr,
					                                            sizeof(struct sockaddr_in6));
					printf("Local IPv6 address: %.*s\n", MDNS_STRING_FORMAT(addr));
				}
			}
		}
	}

	freeifaddrs(ifaddr);

#endif

	return num_sockets;
}

// Open sockets to listen to incoming mDNS queries on port 5353
static int
open_service_sockets(int* sockets, int max_sockets) {
	// When recieving, each socket can recieve data from all network interfaces
	// Thus we only need to open one socket for each address family
	int num_sockets = 0;

	// Call the client socket function to enumerate and get local addresses,
	// but not open the actual sockets
	open_client_sockets(0, 0, 0);

	if (num_sockets < max_sockets) {
		struct sockaddr_in sock_addr;
		memset(&sock_addr, 0, sizeof(struct sockaddr_in));
		sock_addr.sin_family = AF_INET;
#ifdef _WIN32
		sock_addr.sin_addr = in4addr_any;
#else
		sock_addr.sin_addr.s_addr = INADDR_ANY;
#endif
		sock_addr.sin_port = htons(MDNS_PORT);
#ifdef __APPLE__
		sock_addr.sin_len = sizeof(struct sockaddr_in);
#endif
		int sock = mdns_socket_open_ipv4(&sock_addr);
		if (sock >= 0)
			sockets[num_sockets++] = sock;
	}

	if (num_sockets < max_sockets) {
		struct sockaddr_in6 sock_addr;
		memset(&sock_addr, 0, sizeof(struct sockaddr_in6));
		sock_addr.sin6_family = AF_INET6;
		sock_addr.sin6_addr = in6addr_any;
		sock_addr.sin6_port = htons(MDNS_PORT);
#ifdef __APPLE__
		sock_addr.sin6_len = sizeof(struct sockaddr_in6);
#endif
		int sock = mdns_socket_open_ipv6(&sock_addr);
		if (sock >= 0)
			sockets[num_sockets++] = sock;
	}

	return num_sockets;
}

// Send a DNS-SD query
static int
send_dns_sd(void) {
	int sockets[32];
	int num_sockets = open_client_sockets(sockets, sizeof(sockets) / sizeof(sockets[0]), 0);
	if (num_sockets <= 0) {
		printf("Failed to open any client sockets\n");
		return -1;
	}
	printf("Opened %d socket%s for DNS-SD\n", num_sockets, num_sockets > 1 ? "s" : "");

	printf("Sending DNS-SD discovery\n");
	for (int isock = 0; isock < num_sockets; ++isock) {
		if (mdns_discovery_send(sockets[isock]))
			printf("Failed to send DNS-DS discovery: %s\n", strerror(errno));
	}

	size_t capacity = 2048;
	void* buffer = malloc(capacity);
	void* user_data = 0;
	size_t records;

	// This is a simple implementation that loops for 5 seconds or as long as we get replies
	int res;
	printf("Reading DNS-SD replies\n");
	do {
		struct timeval timeout;
		timeout.tv_sec = 5;
		timeout.tv_usec = 0;

		int nfds = 0;
		fd_set readfs;
		FD_ZERO(&readfs);
		for (int isock = 0; isock < num_sockets; ++isock) {
			if (sockets[isock] >= nfds)
				nfds = sockets[isock] + 1;
			FD_SET(sockets[isock], &readfs);
		}

		records = 0;
		res = select(nfds, &readfs, 0, 0, &timeout);
		if (res > 0) {
			for (int isock = 0; isock < num_sockets; ++isock) {
				if (FD_ISSET(sockets[isock], &readfs)) {
					records += mdns_discovery_recv(sockets[isock], buffer, capacity, query_callback,
					                               user_data);
				}
			}
		}
	} while (res > 0);

	free(buffer);

	for (int isock = 0; isock < num_sockets; ++isock)
		mdns_socket_close(sockets[isock]);
	printf("Closed socket%s\n", num_sockets ? "s" : "");

	return 0;
}

// Send a mDNS query
static int
send_mdns_query(mdns_query_t* query, size_t count) {
	int sockets[32];
	int query_id[32];
	int num_sockets = open_client_sockets(sockets, sizeof(sockets) / sizeof(sockets[0]), 0);
	if (num_sockets <= 0) {
		printf("Failed to open any client sockets\n");
		return -1;
	}
	printf("Opened %d socket%s for mDNS query\n", num_sockets, num_sockets ? "s" : "");

	size_t capacity = 2048;
	void* buffer = malloc(capacity);
	void* user_data = 0;

	printf("Sending mDNS query");
	for (size_t iq = 0; iq < count; ++iq) {
		const char* record_name = "PTR";
		if (query[iq].type == MDNS_RECORDTYPE_SRV)
			record_name = "SRV";
		else if (query[iq].type == MDNS_RECORDTYPE_A)
			record_name = "A";
		else if (query[iq].type == MDNS_RECORDTYPE_AAAA)
			record_name = "AAAA";
		else
			query[iq].type = MDNS_RECORDTYPE_PTR;
		printf(" : %s %s", query[iq].name, record_name);
	}
	printf("\n");
	for (int isock = 0; isock < num_sockets; ++isock) {
		query_id[isock] =
		    mdns_multiquery_send(sockets[isock], query, count, buffer, capacity, 0);
		if (query_id[isock] < 0)
			printf("Failed to send mDNS query: %s\n", strerror(errno));
	}

	// This is a simple implementation that loops for 5 seconds or as long as we get replies
	int res;
	printf("Reading mDNS query replies\n");
	int records = 0;
	do {
		struct timeval timeout;
		timeout.tv_sec = 10;
		timeout.tv_usec = 0;

		int nfds = 0;
		fd_set readfs;
		FD_ZERO(&readfs);
		for (int isock = 0; isock < num_sockets; ++isock) {
			if (sockets[isock] >= nfds)
				nfds = sockets[isock] + 1;
			FD_SET(sockets[isock], &readfs);
		}

		res = select(nfds, &readfs, 0, 0, &timeout);
		if (res > 0) {
			for (int isock = 0; isock < num_sockets; ++isock) {
				if (FD_ISSET(sockets[isock], &readfs)) {
					size_t rec = mdns_query_recv(sockets[isock], buffer, capacity, query_callback,
					                             user_data, query_id[isock]);
					if (rec > 0)
						records += rec;
				}
				FD_SET(sockets[isock], &readfs);
			}
		}
	} while (res > 0);

	printf("Read %d records\n", records);

	free(buffer);

	for (int isock = 0; isock < num_sockets; ++isock)
		mdns_socket_close(sockets[isock]);
	printf("Closed socket%s\n", num_sockets ? "s" : "");

	return 0;
}

// Provide a mDNS service, answering incoming DNS-SD and mDNS queries
static int
service_mdns(const char* hostname, const char* service_name, int service_port) {
	int sockets[32];
	int num_sockets = open_service_sockets(sockets, sizeof(sockets) / sizeof(sockets[0]));
	if (num_sockets <= 0) {
		printf("Failed to open any client sockets\n");
		return -1;
	}
	printf("Opened %d socket%s for mDNS service\n", num_sockets, num_sockets ? "s" : "");

	size_t service_name_length = strlen(service_name);
	if (!service_name_length) {
		printf("Invalid service name\n");
		return -1;
	}

	char* service_name_buffer = malloc(service_name_length + 2);
	memcpy(service_name_buffer, service_name, service_name_length);
	if (service_name_buffer[service_name_length - 1] != '.')
		service_name_buffer[service_name_length++] = '.';
	service_name_buffer[service_name_length] = 0;
	service_name = service_name_buffer;

	printf("Service mDNS: %s:%d\n", service_name, service_port);
	printf("Hostname: %s\n", hostname);

	size_t capacity = 2048;
	void* buffer = malloc(capacity);

	mdns_string_t service_string = (mdns_string_t){service_name, strlen(service_name)};
	mdns_string_t hostname_string = (mdns_string_t){hostname, strlen(hostname)};

	// Build the service instance "<hostname>.<_service-name>._tcp.local." string
	char service_instance_buffer[256] = {0};
	snprintf(service_instance_buffer, sizeof(service_instance_buffer) - 1, "%.*s.%.*s",
	         MDNS_STRING_FORMAT(hostname_string), MDNS_STRING_FORMAT(service_string));
	mdns_string_t service_instance_string =
	    (mdns_string_t){service_instance_buffer, strlen(service_instance_buffer)};

	// Build the "<hostname>.local." string
	char qualified_hostname_buffer[256] = {0};
	snprintf(qualified_hostname_buffer, sizeof(qualified_hostname_buffer) - 1, "%.*s.local.",
	         MDNS_STRING_FORMAT(hostname_string));
	mdns_string_t hostname_qualified_string =
	    (mdns_string_t){qualified_hostname_buffer, strlen(qualified_hostname_buffer)};

	service_t service = {0};
	service.service = service_string;
	service.hostname = hostname_string;
	service.service_instance = service_instance_string;
	service.hostname_qualified = hostname_qualified_string;
	service.address_ipv4 = service_address_ipv4;
	service.address_ipv6 = service_address_ipv6;
	service.port = service_port;

	// Setup our mDNS records

	// PTR record reverse mapping "<_service-name>._tcp.local." to
	// "<hostname>.<_service-name>._tcp.local."
	service.record_ptr = (mdns_record_t){.name = service.service,
	                                     .type = MDNS_RECORDTYPE_PTR,
	                                     .data.ptr.name = service.service_instance,
	                                     .rclass = 0,
	                                     .ttl = 0};

	// SRV record mapping "<hostname>.<_service-name>._tcp.local." to
	// "<hostname>.local." with port. Set weight & priority to 0.
	service.record_srv = (mdns_record_t){.name = service.service_instance,
	                                     .type = MDNS_RECORDTYPE_SRV,
	                                     .data.srv.name = service.hostname_qualified,
	                                     .data.srv.port = service.port,
	                                     .data.srv.priority = 0,
	                                     .data.srv.weight = 0,
	                                     .rclass = 0,
	                                     .ttl = 0};

	// A/AAAA records mapping "<hostname>.local." to IPv4/IPv6 addresses
	service.record_a = (mdns_record_t){.name = service.hostname_qualified,
	                                   .type = MDNS_RECORDTYPE_A,
	                                   .data.a.addr = service.address_ipv4,
	                                   .rclass = 0,
	                                   .ttl = 0};

	service.record_aaaa = (mdns_record_t){.name = service.hostname_qualified,
	                                      .type = MDNS_RECORDTYPE_AAAA,
	                                      .data.aaaa.addr = service.address_ipv6,
	                                      .rclass = 0,
	                                      .ttl = 0};

	// Add two test TXT records for our service instance name, will be coalesced into
	// one record with both key-value pair strings by the library
	service.txt_record[0] = (mdns_record_t){.name = service.service_instance,
	                                        .type = MDNS_RECORDTYPE_TXT,
	                                        .data.txt.key = {MDNS_STRING_CONST("test")},
	                                        .data.txt.value = {MDNS_STRING_CONST("1")},
	                                        .rclass = 0,
	                                        .ttl = 0};
	service.txt_record[1] = (mdns_record_t){.name = service.service_instance,
	                                        .type = MDNS_RECORDTYPE_TXT,
	                                        .data.txt.key = {MDNS_STRING_CONST("other")},
	                                        .data.txt.value = {MDNS_STRING_CONST("value")},
	                                        .rclass = 0,
	                                        .ttl = 0};

	// Send an announcement on startup of service
	{
		printf("Sending announce\n");
		mdns_record_t additional[5] = {0};
		size_t additional_count = 0;
		additional[additional_count++] = service.record_srv;
		if (service.address_ipv4.sin_family == AF_INET)
			additional[additional_count++] = service.record_a;
		if (service.address_ipv6.sin6_family == AF_INET6)
			additional[additional_count++] = service.record_aaaa;
		additional[additional_count++] = service.txt_record[0];
		additional[additional_count++] = service.txt_record[1];

		for (int isock = 0; isock < num_sockets; ++isock)
			mdns_announce_multicast(sockets[isock], buffer, capacity, service.record_ptr, 0, 0,
			                        additional, additional_count);
	}

	// This is a crude implementation that checks for incoming queries
	while (running) {
		int nfds = 0;
		fd_set readfs;
		FD_ZERO(&readfs);
		for (int isock = 0; isock < num_sockets; ++isock) {
			if (sockets[isock] >= nfds)
				nfds = sockets[isock] + 1;
			FD_SET(sockets[isock], &readfs);
		}

		struct timeval timeout;
		timeout.tv_sec = 0;
		timeout.tv_usec = 100000;

		if (select(nfds, &readfs, 0, 0, &timeout) >= 0) {
			for (int isock = 0; isock < num_sockets; ++isock) {
				if (FD_ISSET(sockets[isock], &readfs)) {
					mdns_socket_listen(sockets[isock], buffer, capacity, service_callback,
					                   &service);
				}
				FD_SET(sockets[isock], &readfs);
			}
		} else {
			break;
		}
	}

	// Send a goodbye on end of service
	{
		printf("Sending goodbye\n");
		mdns_record_t additional[5] = {0};
		size_t additional_count = 0;
		additional[additional_count++] = service.record_srv;
		if (service.address_ipv4.sin_family == AF_INET)
			additional[additional_count++] = service.record_a;
		if (service.address_ipv6.sin6_family == AF_INET6)
			additional[additional_count++] = service.record_aaaa;
		additional[additional_count++] = service.txt_record[0];
		additional[additional_count++] = service.txt_record[1];

		for (int isock = 0; isock < num_sockets; ++isock)
			mdns_goodbye_multicast(sockets[isock], buffer, capacity, service.record_ptr, 0, 0,
			                        additional, additional_count);
	}

	free(buffer);
	free(service_name_buffer);

	for (int isock = 0; isock < num_sockets; ++isock)
		mdns_socket_close(sockets[isock]);
	printf("Closed socket%s\n", num_sockets ? "s" : "");

	return 0;
}


// Dump all incoming mDNS queries and answers
static int
dump_mdns(void) {
	int sockets[32];
	int num_sockets = open_service_sockets(sockets, sizeof(sockets) / sizeof(sockets[0]));
	if (num_sockets <= 0) {
		printf("Failed to open any client sockets\n");
		return -1;
	}
	printf("Opened %d socket%s for mDNS dump\n", num_sockets, num_sockets ? "s" : "");

	size_t capacity = 2048;
	void* buffer = malloc(capacity);

	// This is a crude implementation that checks for incoming queries and answers
	while (running) {
		int nfds = 0;
		fd_set readfs;
		FD_ZERO(&readfs);
		for (int isock = 0; isock < num_sockets; ++isock) {
			if (sockets[isock] >= nfds)
				nfds = sockets[isock] + 1;
			FD_SET(sockets[isock], &readfs);
		}

		struct timeval timeout;
		timeout.tv_sec = 0;
		timeout.tv_usec = 100000;

		if (select(nfds, &readfs, 0, 0, &timeout) >= 0) {
			for (int isock = 0; isock < num_sockets; ++isock) {
				if (FD_ISSET(sockets[isock], &readfs)) {
					mdns_socket_listen(sockets[isock], buffer, capacity, dump_callback, 0);
				}
				FD_SET(sockets[isock], &readfs);
			}
		} else {
			break;
		}
	}

	free(buffer);

	for (int isock = 0; isock < num_sockets; ++isock)
		mdns_socket_close(sockets[isock]);
	printf("Closed socket%s\n", num_sockets ? "s" : "");

	return 0;
}

#ifdef MDNS_FUZZING

#undef printf

// Fuzzing by piping random data into the recieve functions
static void
fuzz_mdns(void) {
#define MAX_FUZZ_SIZE 4096
#define MAX_PASSES (1024 * 1024 * 1024)

	static uint8_t fuzz_mdns_services_query[] = {
	    0x00, 0x00, 0x00, 0x00, 0x00, 0x01, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x09, '_',
	    's',  'e',  'r',  'v',  'i',  'c',  'e',  's',  0x07, '_',  'd',  'n',  's',  '-',
	    's',  'd',  0x04, '_',  'u',  'd',  'p',  0x05, 'l',  'o',  'c',  'a',  'l',  0x00};

	uint8_t* buffer = malloc(MAX_FUZZ_SIZE);
	uint8_t* strbuffer = malloc(MAX_FUZZ_SIZE);
	for (int ipass = 0; ipass < MAX_PASSES; ++ipass) {
		size_t size = rand() % MAX_FUZZ_SIZE;
		for (size_t i = 0; i < size; ++i)
			buffer[i] = rand() & 0xFF;

		if (ipass % 4) {
			// Crafted fuzzing, make sure header is reasonable
			memcpy(buffer, fuzz_mdns_services_query, sizeof(fuzz_mdns_services_query));
			uint16_t* header = (uint16_t*)buffer;
			header[0] = 0;
			header[1] = htons(0x8400);
			for (int ival = 2; ival < 6; ++ival)
				header[ival] = rand() & 0xFF;
		}
		mdns_discovery_recv(0, (void*)buffer, size, query_callback, 0);

		mdns_socket_listen(0, (void*)buffer, size, service_callback, 0);

		if (ipass % 4) {
			// Crafted fuzzing, make sure header is reasonable (1 question claimed).
			// Earlier passes will have done completely random data
			uint16_t* header = (uint16_t*)buffer;
			header[2] = htons(1);
		}
		mdns_query_recv(0, (void*)buffer, size, query_callback, 0, 0);

		// Fuzzing by piping random data into the parse functions
		size_t offset = size ? (rand() % size) : 0;
		size_t length = size ? (rand() % (size - offset)) : 0;
		mdns_record_parse_ptr(buffer, size, offset, length, strbuffer, MAX_FUZZ_SIZE);

		offset = size ? (rand() % size) : 0;
		length = size ? (rand() % (size - offset)) : 0;
		mdns_record_parse_srv(buffer, size, offset, length, strbuffer, MAX_FUZZ_SIZE);

		struct sockaddr_in addr_ipv4;
		offset = size ? (rand() % size) : 0;
		length = size ? (rand() % (size - offset)) : 0;
		mdns_record_parse_a(buffer, size, offset, length, &addr_ipv4);

		struct sockaddr_in6 addr_ipv6;
		offset = size ? (rand() % size) : 0;
		length = size ? (rand() % (size - offset)) : 0;
		mdns_record_parse_aaaa(buffer, size, offset, length, &addr_ipv6);

		offset = size ? (rand() % size) : 0;
		length = size ? (rand() % (size - offset)) : 0;
		mdns_record_parse_txt(buffer, size, offset, length, (mdns_record_txt_t*)strbuffer,
		                      MAX_FUZZ_SIZE);

		if (ipass && !(ipass % 10000))
			printf("Completed fuzzing pass %d\n", ipass);
	}

	free(buffer);
	free(strbuffer);
}

#endif

#ifdef _WIN32
BOOL console_handler(DWORD signal) {
	if (signal == CTRL_C_EVENT) {
		running = 0;
	}
	return TRUE;
}
#else
void signal_handler(int signal) {
	running = 0;
}
#endif

int
main(int argc, const char* const* argv) {
	int mode = 0;
	const char* service = "_test-mdns._tcp.local.";
	const char* hostname = "dummy-host";
	mdns_query_t query[16];
	size_t query_count = 0;
	int service_port = 42424;

#ifdef _WIN32

	WORD versionWanted = MAKEWORD(1, 1);
	WSADATA wsaData;
	if (WSAStartup(versionWanted, &wsaData)) {
		printf("Failed to initialize WinSock\n");
		return -1;
	}

	char hostname_buffer[256];
	DWORD hostname_size = (DWORD)sizeof(hostname_buffer);
	if (GetComputerNameA(hostname_buffer, &hostname_size))
		hostname = hostname_buffer;

	SetConsoleCtrlHandler(console_handler, TRUE);
#else

	char hostname_buffer[256];
	size_t hostname_size = sizeof(hostname_buffer);
	if (gethostname(hostname_buffer, hostname_size) == 0)
		hostname = hostname_buffer;
	signal(SIGINT, signal_handler);
#endif

	for (int iarg = 0; iarg < argc; ++iarg) {
		if (strcmp(argv[iarg], "--discovery") == 0) {
			mode = 0;
		} else if (strcmp(argv[iarg], "--query") == 0) {
			// Each query is either a service name, or a pair of record type and a service name
			// For example:
			//  mdns --query _foo._tcp.local.
			//  mdns --query SRV myhost._foo._tcp.local.
			//  mdns --query A myhost._tcp.local. _service._tcp.local.
			mode = 1;
			++iarg;
			while ((iarg < argc) && (query_count < 16)) {
				query[query_count].name = argv[iarg++];
				query[query_count].type = MDNS_RECORDTYPE_PTR;
				if (iarg < argc) {
					mdns_record_type_t record_type = 0;
					if (strcmp(query[query_count].name, "PTR") == 0)
						record_type = MDNS_RECORDTYPE_PTR;
					else if (strcmp(query[query_count].name, "SRV") == 0)
						record_type = MDNS_RECORDTYPE_SRV;
					else if (strcmp(query[query_count].name, "A") == 0)
						record_type = MDNS_RECORDTYPE_A;
					else if (strcmp(query[query_count].name, "AAAA") == 0)
						record_type = MDNS_RECORDTYPE_AAAA;
					if (record_type != 0) {
						query[query_count].type = record_type;
						query[query_count].name = argv[iarg++];
					}
				}
				query[query_count].length = strlen(query[query_count].name);
				++query_count;
			}
		} else if (strcmp(argv[iarg], "--service") == 0) {
			mode = 2;
			++iarg;
			if (iarg < argc)
				service = argv[iarg];
		} else if (strcmp(argv[iarg], "--dump") == 0) {
			mode = 3;
		} else if (strcmp(argv[iarg], "--hostname") == 0) {
			++iarg;
			if (iarg < argc)
				hostname = argv[iarg];
		} else if (strcmp(argv[iarg], "--port") == 0) {
			++iarg;
			if (iarg < argc)
				service_port = atoi(argv[iarg]);
		}
	}

#ifdef MDNS_FUZZING
	fuzz_mdns();
#else
	int ret;
	if (mode == 0)
		ret = send_dns_sd();
	else if (mode == 1)
		ret = send_mdns_query(query, query_count);
	else if (mode == 2)
		ret = service_mdns(hostname, service, service_port);
	else if (mode == 3)
		ret = dump_mdns();
#endif

#ifdef _WIN32
	WSACleanup();
#endif

	return 0;
}