lokinet/llarp/dnsc.cpp
despair86 bdc54835c2 initial windows server port. Requires Windows 2000 Server or later.
- updated CMake build script
- builds with Microsoft C++ 19.1x. such builds require Windows 8.1 or later
  unless you have the .NET Server 2003-toolset (v141_xp)
- windows port requires a C++17 compiler since cpp17::filesystem is POSIX-only
- HAVE_CXX17_FILESYSTEM manual toggle in CMake. You must manually specify where
  std::[experimental::]filesystem is defined in LDFLAGS or CMAKE_x_LINKER_FLAGS.
- IPv6 support can be added at any time, and the windows sdk still has that
  inline getaddrinfo(3) if it can't find a suitable IPv6 stack.
- inline code for mingw-w64: there's a few bits and pieces still missing simply because
  mingw-w64 derives its windows sdk from wine and reactos, and then writing all the newer
  stuff into it by hand straight from the MSDN manpages.
- misc. C++11 stuff (nullptr and friends)
- Internal file handling code takes UTF-8 or plain 8-bit text, NTFS is UTF-16, so
  std::filesystem::path::c_str() is wchar_t. That's no good unless you first
  call std::filesystem::path::string().
- implemented getifaddrs(3) and if_nametoindex(3) on top of GetAdapters[Info|Addresses](2).
- updated readme with new info

BONUS: may implement Solaris/illumos IOCP someday...

-despair86
2018-08-01 23:41:02 -05:00

630 lines
19 KiB
C++

#include "dnsc.hpp"
#include <llarp/dns.h>
#include "buffer.hpp"
#ifndef _WIN32
#include <arpa/inet.h>
#include <netdb.h> /* getaddrinfo, getnameinfo */
#include <netinet/in.h>
#include <sys/socket.h>
#endif
#include <stdlib.h> /* exit */
#include <string.h> /* memset */
#include <sys/types.h>
#ifndef _MSC_VER
#include <unistd.h> /* close */
#endif
#include <cstdio>
#include <llarp/dns.h>
#include "llarp/net.hpp" // for llarp::Addr
#include "logger.hpp"
// FIXME: make configurable
#define SERVER "8.8.8.8"
#define PORT 53
#define DNC_BUF_SIZE 512
// a question to be asked remotely
// header, question
struct dns_query
{
uint16_t length;
// char *url;
unsigned char request[DNC_BUF_SIZE];
// uint16_t reqType;
};
struct dns_query *
build_dns_packet(char *url, uint16_t id, uint16_t reqType)
{
dns_query *dnsQuery = new dns_query;
dnsQuery->length = 12;
// ID
// buffer[0] = (value & 0xFF00) >> 8;
// buffer[1] = value & 0xFF;
llarp::LogDebug("building request ", id);
dnsQuery->request[0] = (id & 0xFF00) >> 8;
dnsQuery->request[1] = (id & 0x00FF) >> 0;
// field
dnsQuery->request[2] = 0x01;
dnsQuery->request[3] = 0x00;
// questions
dnsQuery->request[4] = 0x00;
dnsQuery->request[5] = 0x01;
// answers
dnsQuery->request[6] = 0x00;
dnsQuery->request[7] = 0x00;
// ns
dnsQuery->request[8] = 0x00;
dnsQuery->request[9] = 0x00;
// ar
dnsQuery->request[10] = 0x00;
dnsQuery->request[11] = 0x00;
char *word;
// llarp::LogDebug("Asking DNS server %s about %s", SERVER, dnsQuery->url);
char *strTemp = strdup(url);
word = strtok(strTemp, ".");
while(word)
{
// llarp::LogDebug("parsing hostname: \"%s\" is %zu characters", word,
// strlen(word));
dnsQuery->request[dnsQuery->length++] = strlen(word);
for(unsigned int i = 0; i < strlen(word); i++)
{
dnsQuery->request[dnsQuery->length++] = word[i];
}
word = strtok(nullptr, ".");
}
dnsQuery->request[dnsQuery->length++] = 0x00; // End of the host name
dnsQuery->request[dnsQuery->length++] =
0x00; // 0x0001 - Query is a Type A query (host address)
dnsQuery->request[dnsQuery->length++] = reqType;
dnsQuery->request[dnsQuery->length++] =
0x00; // 0x0001 - Query is class IN (Internet address)
dnsQuery->request[dnsQuery->length++] = 0x01;
return dnsQuery;
}
struct sockaddr *
raw_resolve_host(const char *url)
{
// char *sUrl = strdup(url);
// struct dns_query dnsQuery;
dns_query *dns_packet = build_dns_packet((char *)url, 0xDB42, 1);
/*
dnsQuery.length = 12;
dnsQuery.url = sUrl;
dnsQuery.reqType = 0x01;
// dnsQuery.request = { 0xDB, 0x42, 0x01, 0x00, 0x00, 0x01, 0x00, 0x00, 0x00,
// 0x00, 0x00, 0x00 };
dnsQuery.request[0] = 0xDB;
dnsQuery.request[1] = 0x42;
dnsQuery.request[2] = 0x01;
dnsQuery.request[3] = 0x00;
dnsQuery.request[4] = 0x00;
dnsQuery.request[5] = 0x01;
dnsQuery.request[6] = 0x00;
dnsQuery.request[7] = 0x00;
dnsQuery.request[8] = 0x00;
dnsQuery.request[9] = 0x00;
dnsQuery.request[10] = 0x00;
dnsQuery.request[11] = 0x00;
*/
// char *word;
unsigned int i;
llarp::LogDebug("Asking DNS server ", SERVER, " about ", url);
// dnsQuery.reqType = 0x01;
/*
word = strtok(sUrl, ".");
while(word)
{
llarp::LogDebug("parsing hostname: \"%s\" is %zu characters\n", word,
strlen(word));
dnsQuery.request[dnsQuery.length++] = strlen(word);
for(i = 0; i < strlen(word); i++)
{
dnsQuery.request[dnsQuery.length++] = word[i];
}
word = strtok(nullptr, ".");
}
dnsQuery.request[dnsQuery.length++] = 0x00; // End of the host name
dnsQuery.request[dnsQuery.length++] =
0x00; // 0x0001 - Query is a Type A query (host address)
dnsQuery.request[dnsQuery.length++] = dnsQuery.reqType;
dnsQuery.request[dnsQuery.length++] =
0x00; // 0x0001 - Query is class IN (Internet address)
dnsQuery.request[dnsQuery.length++] = 0x01;
*/
struct sockaddr_in addr;
// int socket;
ssize_t ret;
int rcode;
socklen_t size;
int ip = 0;
// int length;
unsigned char buffer[DNC_BUF_SIZE];
// unsigned char tempBuf[3];
uint16_t QDCOUNT; // No. of items in Question Section
uint16_t ANCOUNT; // No. of items in Answer Section
uint16_t NSCOUNT; // No. of items in Authority Section
uint16_t ARCOUNT; // No. of items in Additional Section
// uint16_t QCLASS; // Specifies the class of the query
uint16_t ATYPE; // Specifies the meaning of the data in the RDATA field
// uint16_t ACLASS; // Specifies the class of the data in the RDATA field
// uint32_t TTL; // The number of seconds the results can be cached
// uint16_t RDLENGTH; // The length of the RDATA field
// uint16_t MSGID;
#ifndef _WIN32
int sockfd;
#else
SOCKET sockfd;
#endif
sockfd = socket(AF_INET, SOCK_DGRAM, 0);
if(sockfd < 0)
{
llarp::LogWarn("Error creating socket!\n");
return nullptr;
}
// socket = sockfd;
memset(&addr, 0, sizeof(addr));
addr.sin_family = AF_INET;
addr.sin_addr.s_addr = inet_addr(SERVER);
addr.sin_port = htons(PORT);
size = sizeof(addr);
// hexdump("sending packet", &dnsQuery.request, dnsQuery.length);
#ifdef _WIN32
ret = sendto(sockfd, (const char *)dns_packet->request, dns_packet->length, 0,
(struct sockaddr *)&addr, size);
#else
ret = sendto(sockfd, dns_packet->request, dns_packet->length, 0,
(struct sockaddr *)&addr, size);
#endif
delete dns_packet;
if(ret < 0)
{
llarp::LogWarn("Error Sending Request");
return nullptr;
}
// llarp::LogInfo("Sent\n");
memset(&buffer, 0, DNC_BUF_SIZE);
#ifdef _WIN32
ret = recvfrom(sockfd, (char *)buffer, DNC_BUF_SIZE, 0,
(struct sockaddr *)&addr, &size);
#else
ret = recvfrom(sockfd, buffer, DNC_BUF_SIZE, 0,
(struct sockaddr *)&addr, &size);
#endif
if(ret < 0)
{
llarp::LogWarn("Error Receiving Response");
return nullptr;
}
// hexdump("received packet", &buffer, ret);
#ifndef _WIN32
close(sockfd);
#else
closesocket(sockfd);
#endif
rcode = (buffer[3] & 0x0F);
// tempBuf[0] = buffer[4];
// tempBuf[1] = buffer[5];
// tempBuf[2] = '\0';
// printf("%0x %0x %0x %0x\n", buffer[4], buffer[5], tempBuf[0], tempBuf[1]);
// QDCOUNT = (uint16_t) strtol(tempBuf, nullptr, 16);
QDCOUNT = (uint16_t)buffer[4] * 0x100 + buffer[5];
llarp::LogDebug("entries in question section: %u\n", QDCOUNT);
ANCOUNT = (uint16_t)buffer[6] * 0x100 + buffer[7];
llarp::LogDebug("records in answer section: %u\n", ANCOUNT);
NSCOUNT = (uint16_t)buffer[8] * 0x100 + buffer[9];
llarp::LogDebug("name server resource record count: %u\n", NSCOUNT);
ARCOUNT = (uint16_t)buffer[10] * 0x100 + buffer[11];
llarp::LogDebug("additional records count: %u\n", ARCOUNT);
/*
llarp::LogDebug("query type: %u\n", dnsQuery.reqType);
QCLASS = (uint16_t)dnsQuery.request[dnsQuery.length - 2] * 0x100
+ dnsQuery.request[dnsQuery.length - 1];
llarp::LogDebug("query class: %u\n", QCLASS);
length = dnsQuery.length + 1; // to skip 0xc00c
ATYPE = (uint16_t)buffer[length + 1] * 0x100 + buffer[length + 2];
llarp::LogDebug("answer type: %u\n", ATYPE);
ACLASS = (uint16_t)buffer[length + 3] * 0x100 + buffer[length + 4];
llarp::LogDebug("answer class: %u\n", ACLASS);
TTL = (uint32_t)buffer[length + 5] * 0x1000000 + buffer[length + 6] * 0x10000
+ buffer[length + 7] * 0x100 + buffer[length + 8];
llarp::LogDebug("seconds to cache: %u\n", TTL);
RDLENGTH = (uint16_t)buffer[length + 9] * 0x100 + buffer[length + 10];
llarp::LogDebug("bytes in answer: %u\n", RDLENGTH);
MSGID = (uint16_t)buffer[0] * 0x100 + buffer[1];
llarp::LogDebug("answer msg id: %u\n", MSGID);
*/
if(rcode == 2)
{
llarp::LogWarn("nameserver %s returned SERVFAIL:\n", SERVER);
llarp::LogWarn(
" the name server was unable to process this query due to a\n "
"problem with the name server.\n");
return nullptr;
}
else if(rcode == 3)
{
llarp::LogWarn("nameserver %s returned NXDOMAIN for ", SERVER);
llarp::LogWarn(
" the domain name referenced in the query does not exist\n");
return nullptr;
}
/* search for and print IPv4 addresses */
// if(dnsQuery.reqType == 0x01)
if(1)
{
llarp::LogDebug("DNS server's answer is: (type#=%u):", ATYPE);
// printf("IPv4 address(es) for %s:\n", dnsQuery.url);
for(i = 0; i < ret; i++)
{
if(buffer[i] == 0xC0 && buffer[i + 3] == 0x01)
{
ip++;
i += 12; /* ! += buf[i+1]; */
llarp::LogDebug(" %u.%u.%u.%u\n", buffer[i], buffer[i + 1],
buffer[i + 2], buffer[i + 3]);
struct sockaddr *g_addr = new sockaddr;
g_addr->sa_family = AF_INET;
#if((__APPLE__ && __MACH__) || __FreeBSD__)
g_addr->sa_len = sizeof(in_addr);
#endif
struct in_addr *addr = &((struct sockaddr_in *)g_addr)->sin_addr;
unsigned char *ip;
// have ip point to s_addr
ip = (unsigned char *)&(addr->s_addr);
ip[0] = buffer[i + 0];
ip[1] = buffer[i + 1];
ip[2] = buffer[i + 2];
ip[3] = buffer[i + 3];
return g_addr;
}
}
if(!ip)
{
llarp::LogWarn(" No IPv4 address found in the DNS response!\n");
return nullptr;
}
}
return nullptr;
}
void
llarp_handle_dnsc_recvfrom(struct llarp_udp_io *udp,
const struct sockaddr *saddr, const void *buf,
ssize_t sz)
{
// lock_t lock(m_dnsc_Mutex);
// llarp::LogInfo("got a response, udp user is ", udp->user);
unsigned char *castBuf = (unsigned char *)buf;
// auto buffer = llarp::StackBuffer< decltype(castBuf) >(castBuf);
dns_msg_header *hdr = decode_hdr((const char *)castBuf);
llarp::LogDebug("Header got client responses for id: ", hdr->id);
// if we sent this out, then there's an id
struct dns_tracker *tracker = (struct dns_tracker *)udp->user;
struct dnsc_answer_request *request = tracker->client_request[hdr->id];
if(!request)
{
llarp::LogError(
"User data to DNS Client response not a dnsc_answer_request");
// we can't call back the hook
return;
}
// llarp_dnsc_unbind(request);
if(sz < 0)
{
llarp::LogWarn("Error Receiving DNS Client Response");
request->resolved(request);
return;
}
// unsigned char *castBuf = (unsigned char *)buf;
// auto buffer = llarp::StackBuffer< decltype(castBuf) >(castBuf);
// hexdump("received packet", &buffer, ret);
/*
uint16_t QDCOUNT; // No. of items in Question Section
uint16_t ANCOUNT; // No. of items in Answer Section
uint16_t NSCOUNT; // No. of items in Authority Section
uint16_t ARCOUNT; // No. of items in Additional Section
uint16_t QCLASS; // Specifies the class of the query
uint16_t ATYPE; // Specifies the meaning of the data in the RDATA field
uint16_t ACLASS; // Specifies the class of the data in the RDATA field
uint32_t TTL; // The number of seconds the results can be cached
uint16_t RDLENGTH; // The length of the RDATA field
uint16_t MSGID;
*/
uint8_t rcode;
// int length;
// struct dns_query *dnsQuery = &request->query;
// rcode = (buffer[3] & 0x0F);
// llarp::LogInfo("dnsc rcode ", rcode);
dns_msg_header *msg = decode_hdr((const char *)castBuf);
castBuf += 12;
llarp::LogDebug("msg id ", msg->id);
uint8_t qr = msg->qr;
llarp::LogDebug("msg qr ", qr);
uint8_t opcode = msg->opcode;
llarp::LogDebug("msg op ", opcode);
rcode = msg->rcode;
llarp::LogDebug("msg rc ", rcode);
llarp::LogDebug("msg qdc ", msg->qdCount);
llarp::LogDebug("msg anc ", msg->anCount);
llarp::LogDebug("msg nsc ", msg->nsCount);
llarp::LogDebug("msg arc ", msg->arCount);
// we may need to parse question first
/*
dns_msg_question *question = decode_question((const char *)castBuf);
llarp::LogInfo("que name ", question->name);
castBuf += question->name.length() + 8;
dns_msg_answer *answer = decode_answer((const char *)castBuf);
castBuf += answer->name.length() + 4 + 4 + 4 + answer->rdLen;
*/
// FIXME: only handling one atm
dns_msg_question *question = nullptr;
for(uint i = 0; i < hdr->qdCount; i++)
{
question = decode_question((const char *)castBuf);
llarp::LogDebug("Read a question");
castBuf += question->name.length() + 8;
}
// FIXME: only handling one atm
dns_msg_answer *answer = nullptr;
for(uint i = 0; i < hdr->anCount; i++)
{
answer = decode_answer((const char *)castBuf);
llarp::LogDebug("Read an answer");
castBuf += answer->name.length() + 4 + 4 + 4 + answer->rdLen;
}
// handle authority records (usually no answers with these, so we'll just
// stomp) usually NS records tho
for(uint i = 0; i < hdr->nsCount; i++)
{
answer = decode_answer((const char *)castBuf);
llarp::LogDebug("Read an authority");
castBuf += answer->name.length() + 4 + 4 + 4 + answer->rdLen;
}
// dns_msg_answer *answer2 = decode_answer((const char*)castBuf);
// castBuf += answer->name.length() + 4 + 4 + 4 + answer->rdLen;
// llarp::LogDebug("query type: %u\n", dnsQuery->reqType);
/*
QCLASS = (uint16_t)dnsQuery->request[dnsQuery->length - 2] * 0x100
+ dnsQuery->request[dnsQuery->length - 1];
llarp::LogInfo("query class: ", QCLASS);
length = dnsQuery->length + 1; // to skip 0xc00c
// printf("length [%d] from [%d]\n", length, buffer.base);
ATYPE = (uint16_t)buffer[length + 1] * 0x100 + buffer[length + 2];
llarp::LogInfo("answer type: ", ATYPE);
ACLASS = (uint16_t)buffer[length + 3] * 0x100 + buffer[length + 4];
llarp::LogInfo("answer class: ", ACLASS);
TTL = (uint32_t)buffer[length + 5] * 0x1000000 + buffer[length + 6] * 0x10000
+ buffer[length + 7] * 0x100 + buffer[length + 8];
llarp::LogInfo("seconds to cache: ", TTL);
RDLENGTH = (uint16_t)buffer[length + 9] * 0x100 + buffer[length + 10];
llarp::LogInfo("bytes in answer: ", RDLENGTH);
MSGID = (uint16_t)buffer[0] * 0x100 + buffer[1];
// llarp::LogDebug("answer msg id: %u\n", MSGID);
*/
if(answer == nullptr)
{
llarp::LogWarn("nameserver ", SERVER, " didnt return any answers:");
request->resolved(request);
return;
}
llarp::LogDebug("ans class ", answer->aClass);
llarp::LogDebug("ans type ", answer->type);
llarp::LogDebug("ans ttl ", answer->ttl);
llarp::LogDebug("ans rdlen ", answer->rdLen);
/*
llarp::LogInfo("ans2 class ", answer2->aClass);
llarp::LogInfo("ans2 type ", answer2->type);
llarp::LogInfo("ans2 ttl ", answer2->ttl);
llarp::LogInfo("ans2 rdlen ", answer2->rdLen);
*/
if(rcode == 2)
{
llarp::LogWarn("nameserver ", SERVER, " returned SERVFAIL:");
llarp::LogWarn(
" the name server was unable to process this query due to a problem "
"with the name server.");
request->resolved(request);
return;
}
else if(rcode == 3)
{
llarp::LogWarn("nameserver ", SERVER,
" returned NXDOMAIN for: ", request->question.name);
llarp::LogWarn(" the domain name referenced in the query does not exist");
request->resolved(request);
return;
}
int ip = 0;
/* search for and print IPv4 addresses */
// if(dnsQuery->reqType == 0x01)
if(request->question.type == 1)
{
// llarp::LogInfo("DNS server's answer is: (type#=", ATYPE, "):");
llarp::LogDebug("IPv4 address(es) for ", request->question.name, ":");
if(answer->rdLen == 4)
{
request->result.sa_family = AF_INET;
#if((__APPLE__ && __MACH__) || __FreeBSD__)
request->result.sa_len = sizeof(in_addr);
#endif
struct in_addr *addr =
&((struct sockaddr_in *)&request->result)->sin_addr;
unsigned char *ip = (unsigned char *)&(addr->s_addr);
ip[0] = answer->rData[0];
ip[1] = answer->rData[1];
ip[2] = answer->rData[2];
ip[3] = answer->rData[3];
llarp::Addr test(request->result);
llarp::LogDebug(test);
request->found = true;
request->resolved(request);
return;
}
if(!ip)
{
llarp::LogWarn(" No IPv4 address found in the DNS answer!");
request->resolved(request);
return;
}
}
}
bool
llarp_resolve_host(struct dnsc_context *dnsc, const char *url,
dnsc_answer_hook_func resolved, void *user)
{
dnsc_answer_request *request = new dnsc_answer_request;
request->sock = (void *)&dnsc->udp;
request->user = user;
request->resolved = resolved;
request->found = false;
request->context = dnsc;
char *sUrl = strdup(url);
request->question.name = sUrl;
request->question.type = 1;
request->question.qClass = 1;
// register request with udp response tracker
dns_tracker *tracker = (dns_tracker *)dnsc->udp->user;
/*
uint16_t length = 0;
dns_msg_header header;
header.id = htons(id);
header.qr = 0;
header.opcode = 0;
header.aa = 0;
header.tc = 0;
header.rd = 1;
header.ra = 0;
header.rcode = 0;
header.qdCount = htons(1);
header.anCount = 0;
header.nsCount = 0;
header.arCount = 0;
length += 12;
//request->question.name = sUrl;
request->question.type = htons(1);
request->question.qClass = htons(1);
uint16_t qLen = request->question.name.length() + 8;
length += qLen;
unsigned char bytes[length];
// memcpy isn't going to fix the network endian issue
// encode header into bytes
memcpy(bytes, &header, 12);
// encode question into bytes
memcpy(bytes + 12, &request->question, qLen);
*/
uint16_t id = ++tracker->c_requests;
tracker->client_request[id] = request;
// llarp::LogInfo("Sending request #", tracker->c_requests, " ", length, "
// bytes");
dns_query *dns_packet = build_dns_packet((char *)url, id, 1);
// ssize_t ret = llarp_ev_udp_sendto(dnsc->udp, dnsc->server, bytes, length);
ssize_t ret = llarp_ev_udp_sendto(dnsc->udp, dnsc->server,
dns_packet->request, dns_packet->length);
delete dns_packet;
if(ret < 0)
{
llarp::LogWarn("Error Sending Request");
return false;
}
return true;
}
void
llarp_host_resolved(dnsc_answer_request *request)
{
delete request;
}
bool
llarp_dnsc_init(struct dnsc_context *dnsc, struct llarp_udp_io *udp,
const char *dnsc_hostname, uint16_t dnsc_port)
{
sockaddr_in *trgaddr = new sockaddr_in;
trgaddr->sin_addr.s_addr = inet_addr(dnsc_hostname);
trgaddr->sin_port = htons(dnsc_port);
trgaddr->sin_family = AF_INET;
dnsc->server = (sockaddr *)trgaddr;
dnsc->udp = udp;
return true;
}
bool
llarp_dnsc_stop(struct dnsc_context *dnsc)
{
delete(sockaddr_in *)dnsc->server; // deallocation
return true;
}