libcw/cwSocket.cpp

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#include "cwCommon.h"
#include "cwLog.h"
#include "cwCommonImpl.h"
#include "cwMem.h"
#include "cwThread.h"
#include <sys/socket.h>
#include <sys/ioctl.h>
#include <net/if.h>
#include <netinet/in.h>
#include <arpa/inet.h>
#include <fcntl.h>
#include <unistd.h> // close
#include <poll.h>
#include "cwSocket.h"
#define cwSOCKET_SYS_ERR (-1)
#define cwSOCKET_NULL_SOCK (-1)
#ifndef HOST_NAME_MAX
#define HOST_NAME_MAX _POSIX_HOST_NAME_MAX
#endif
namespace cw
{
namespace sock
{
enum
{
kIsConnectedFl = 0x01,
kIsBlockingFl = 0x02
};
typedef struct sock_str
{
unsigned userId;
unsigned connId;
int sockH;
unsigned createFlags;
unsigned flags;
callbackFunc_t cbFunc;
void* cbArg;
struct sockaddr_in localSockAddr;
struct sockaddr_in remoteSockAddr;
char ntopBuf[ INET_ADDRSTRLEN+1 ]; // use INET6_ADDRSTRLEN for IPv6
char hnameBuf[ HOST_NAME_MAX+1 ];
struct pollfd* pollfd;
unsigned nextConnId;
struct sock_str* parent; // pointer to this socket's parent socket
struct sock_str* children; // pointer to this sockets children (parent==NULL), or sibling (parent!=NULL)
} sock_t;
typedef struct mgr_str
{
uint8_t* buf; // buf[bufByteN]
unsigned bufByteN; // size of buf[]
struct pollfd* pollfdA; // pollfdA[ sockMaxN ] poll array
sock_t* sockA; //.sockA[ sockMaxN ]
unsigned sockMaxN; // sockMaxN count of elements in sockA[] and pollfdA[]
unsigned sockN; // sockA[ sockN ] sock record in use
} mgr_t;
mgr_t* _handleToPtr( handle_t h)
{ return handleToPtr<handle_t,mgr_t>(h); }
sock_t* _idToSock( mgr_t* p, unsigned userId, bool showErrorFl=false )
{
for(unsigned i=0; i<p->sockN; ++i)
if( p->sockA[i].userId == userId )
return p->sockA + i;
if( showErrorFl )
cwLogError(kInvalidIdRC,"A socket with id:%i could not be found.",userId);
return nullptr;
}
rc_t _getMgrAndSocket( handle_t h, unsigned userId, mgr_t*& p, sock_t*& s, bool showErrorFl = false )
{
p = _handleToPtr(h);
if((s = _idToSock(p,userId,showErrorFl)) == nullptr )
return kInvalidArgRC;
return kOkRC;
}
bool _sockIsOpen( sock_t* p )
{ return p->sockH != cwSOCKET_NULL_SOCK; }
void _unlinkChild( sock_t* s )
{
sock_t* ps = s->parent;
sock_t* cs0 = nullptr;
for(sock_t* cs=ps->children; cs!=nullptr; cs=cs->children)
{
if( cs == s )
{
if( cs0 == nullptr )
ps->children = cs->children;
else
cs0->children = cs->children;
cs->children = nullptr;
cs->parent = nullptr;
break;
}
cs0 = cs;
}
}
rc_t _closeSock( mgr_t* p, sock_t* s )
{
rc_t rc = kOkRC;
// close the socket
if( s->sockH != cwSOCKET_NULL_SOCK )
{
errno = 0;
if( ::close(s->sockH) != 0 )
rc = cwLogSysError(kOpFailRC,errno,"The socket close failed." );
s->sockH = cwSOCKET_NULL_SOCK;
}
if( s->parent != nullptr )
_unlinkChild( s );
s->userId = kInvalidId;
s->createFlags = 0;
s->flags = 0;
s->pollfd->events = 0;
s->pollfd->fd = cwSOCKET_NULL_SOCK; // poll() ignores records when fd < 0
s->remoteSockAddr.sin_family = AF_UNSPEC;
return rc;
}
rc_t _destroyMgr( mgr_t* p )
{
rc_t rc = kOkRC;
for(unsigned i=0; i<p->sockN; ++i)
{
rc_t rc0 = _closeSock(p,p->sockA + i);
if( rc0 != kOkRC )
rc = rc0;
}
mem::release(p->sockA);
mem::release(p->pollfdA);
mem::release(p->buf);
mem::release(p);
return rc;
}
// Locate an available slot in p->sockA and return the index of the slot in availIdxRef.
rc_t _locateAvailSlot( mgr_t* p, unsigned& availIdx_Ref )
{
availIdx_Ref = kInvalidIdx;
// locate an avail. socket between 0:sockN
for(unsigned i=0; i<p->sockN; ++i)
if( !_sockIsOpen(p->sockA + i) )
{
availIdx_Ref = i;
return kOkRC;
}
// Be sure all slots are not already in use.
if( p->sockN >= p->sockMaxN )
return cwLogError(kResourceNotAvailableRC,"All socket slots are in use.");
// Expand the slot array to accommodate another socket
availIdx_Ref = p->sockN;
p->sockN += 1;
return kOkRC;
}
void _callback( sock_t* s, cbOpId_t opId, const struct sockaddr_in* srcAddr=nullptr, const void* buf=nullptr, unsigned bufByteN=0 )
{
if( s->cbFunc != nullptr )
s->cbFunc( s->cbArg, opId, s->userId, s->connId, buf, bufByteN, srcAddr );
}
rc_t _accept( mgr_t* p, sock_t* s )
{
rc_t rc = kOkRC;
struct sockaddr_storage remoteAddr;
socklen_t sin_size = sizeof(remoteAddr);
int fd;
unsigned sockIdx = kInvalidIdx;
sock_t* cs = nullptr;
// accept the incoming connection
if((fd = accept(s->sockH, (struct sockaddr*)&remoteAddr, &sin_size )) < 0)
{
if( errno == EAGAIN || errno == EWOULDBLOCK )
rc = kTimeOutRC;
else
{
rc = cwLogSysError(kOpFailRC,errno,"Socket accept() failed.");
goto errLabel;
}
}
// ... then find an available socket record
if((rc = _locateAvailSlot(p, sockIdx )) != kOkRC )
{
rc = cwLogError(rc,"There are no available slots to 'accept' a new socket connection.");
goto errLabel;
}
// initialize the socket record
cs = p->sockA + sockIdx;
cs->userId = s->userId;
cs->connId = s->nextConnId++;
cs->sockH = fd;
cs->createFlags = 0;
cs->remoteSockAddr = *(struct sockaddr_in*)&remoteAddr;
cs->cbFunc = s->cbFunc;
cs->cbArg = s->cbArg;
cs->pollfd = p->pollfdA + sockIdx;
cs->pollfd->events = POLLIN;
cs->pollfd->fd = fd;
cs->nextConnId = 0;
cs->parent = s;
cs->children = s->children;
s->children = cs;
if((rc = addrToString( (const struct sockaddr_in*)&remoteAddr, cs->ntopBuf, sizeof(cs->ntopBuf) )) != kOkRC )
goto errLabel;
_callback( cs, kConnectCbId, (const struct sockaddr_in*)&remoteAddr);
errLabel:
if( rc != kOkRC )
close(fd);
return rc;
}
// Called to read the socket when data is known to be waiting.
rc_t _receive( mgr_t* p, sock_t* s, unsigned& readN_Ref, void* buf=nullptr, unsigned bufByteN=0, struct sockaddr_in* fromAddr=nullptr )
{
rc_t rc = kOkRC;
void* b = buf;
unsigned bN = bufByteN;
ssize_t bytesReadN = 0;
struct sockaddr_in sockaddr;
socklen_t sizeOfFromAddr = 0;
memset(&sockaddr,0,sizeof(sockaddr));
// clear the count of actual bytes read
readN_Ref = 0;
// if the socket is not open then there is nothing to do
if( !_sockIsOpen(s) )
return cwLogWarningRC( kResourceNotAvailableRC, "An attempt was made to read from a closed socket.");
// if no buffer was given then use the default buffer
if( b ==nullptr || bufByteN == 0 )
{
b = p->buf;
bN = p->bufByteN;
}
// if no src address buffer was given and this is a UDP socket
if( fromAddr == nullptr && cwIsNotFlag(s->createFlags,kTcpFl) )
{
fromAddr = &sockaddr;
sizeOfFromAddr = sizeof(struct sockaddr_in);
}
errno = 0;
// read the socket
if((bytesReadN = recvfrom(s->sockH, b, bN, 0, (struct sockaddr*)fromAddr, &sizeOfFromAddr )) != cwSOCKET_SYS_ERR )
{
// return the count of actual bytes read
readN_Ref = bytesReadN;
// if no return buffer was given and the socket has a callback function - then call it
if( bytesReadN > 0 && s->cbFunc != nullptr && (buf==nullptr || bufByteN==0) )
{
// if no src addr was given (because this is a TCP socket) then use the connected remote socket
if( fromAddr == nullptr && s->remoteSockAddr.sin_family != AF_UNSPEC)
fromAddr = &s->remoteSockAddr;
_callback( s, kReceiveCbId, fromAddr, b, bytesReadN );
}
}
else
{
// an error occurred during the read operation
switch( errno )
{
case EAGAIN:
return kTimeOutRC;
case ENOTCONN:
if( cwIsFlag(s->flags,kIsConnectedFl ) )
cwLogWarning("Socket Disconnected.");
s->flags = cwClrFlag(s->flags,kIsConnectedFl);
_callback( s, kDisconnectCbId );
}
return cwLogSysError(kOpFailRC,errno,"recvfrom() failed.");
}
return rc;
}
// Block on devices waiting for data on a port.
// If userId is valid then wait for data on a specific port otherwise
// wait for data on all ports.
rc_t _poll( mgr_t* p, unsigned timeOutMs, unsigned& readN_Ref, unsigned userId=kInvalidId, void* buf=nullptr, unsigned bufByteN=0, struct sockaddr_in* fromAddr=nullptr )
{
rc_t rc = kOkRC;
int sysRC;
readN_Ref = 0;
// if there are not ports then there is nothing to do
if( p->sockN == 0 )
return rc;
struct pollfd* pfd = p->pollfdA; // first struct pollfd
unsigned pfdN = p->sockN; // count of pollfd's
sock_t* s = p->sockA; // port assoc'd with first pollfd
// if only one socket is to be read ...
if( userId != kInvalidId )
{
// ... then locate it
if((s = _idToSock(p,userId)) == nullptr )
return kInvalidArgRC;
pfd = s->pollfd;
pfdN = 1;
}
// A port to poll must exist
if( p == nullptr )
return cwLogError(kInvalidArgRC,"The port with id %i could not be found.",userId);
// block waiting for data on one of the ports
if((sysRC = ::poll(pfd,pfdN,timeOutMs)) == 0)
{
rc = kTimeOutRC;
}
else
{
// ::poll() encountered a system exception
if( sysRC < 0 )
return cwLogSysError(kReadFailRC,errno,"Poll failed on socket.");
// store the current sockA[] size because p->sockN may change inside the loop
unsigned sockN = p->sockN;
// interate through the ports looking for the sockets which have data waiting ...
for(unsigned i=0; i<sockN; ++i)
{
// if the socket was disconnected or is no longer valid
if( cwIsFlag(p->sockA[i].pollfd->revents,POLLHUP) || cwIsFlag(p->sockA[i].pollfd->revents,POLLNVAL) )
{
_callback( p->sockA + i, kDisconnectCbId );
_closeSock(p,p->sockA+i);
continue;
}
// if an error occured on this socket
if( p->sockA[i].pollfd->revents & POLLERR )
{
cwLogError(kOpFailRC,"ERROR on socket user id:%i conn id:%i\n",p->sockA[i].userId,p->sockA[i].connId);
// TODO: should the socket be closed? marked as disconnected?
}
if( p->sockA[i].pollfd->revents & POLLIN )
{
unsigned actualReadN = 0;
sock_t* s = p->sockA + i;
// If this is a listening/streaming socket then it is waiting for connections
if( cwAllFlags(s->createFlags,kListenFl|kStreamFl) )
{
rc_t rc0;
// accept a new connection to this socket
if((rc0 = _accept( p, s)) != kOkRC )
rc = rc0;
}
else // otherwise it is a non-listening socket that is receiving data
{
if((rc = _receive( p, s, actualReadN, buf, bufByteN, fromAddr )) != kOkRC )
return rc;
}
readN_Ref += actualReadN;
}
}
}
return rc;
}
rc_t _initAddr( const char* addrStr, portNumber_t portNumber, struct sockaddr_in* retAddrPtr )
{
memset(retAddrPtr,0,sizeof(struct sockaddr_in));
//if( portNumber == kInvalidPortNumber )
// return cwLogError(kInvalidArgRC,"The port number %i cannot be used.",kInvalidPortNumber);
if( addrStr == nullptr )
retAddrPtr->sin_addr.s_addr = htonl(INADDR_ANY);
else
{
errno = 0;
if(inet_pton(AF_INET,addrStr,&retAddrPtr->sin_addr) == 0 )
return cwLogSysError(kOpFailRC,errno, "The network address string '%s' could not be converted to a netword address structure.",cwStringNullGuard(addrStr) );
}
//retAddrPtr->sin_len = sizeof(struct sockaddr_in);
retAddrPtr->sin_family = AF_INET;
if( portNumber != kInvalidPortNumber )
retAddrPtr->sin_port = htons(portNumber);
return kOkRC;
}
rc_t _connect( sock_t* s, const char* remoteAddr, portNumber_t remotePort )
{
struct sockaddr_in addr;
rc_t rc;
// create the remote address
if((rc = _initAddr( remoteAddr, remotePort, &addr )) != kOkRC )
return rc;
errno = 0;
// ... and connect this socket to the remote address/port
if( connect(s->sockH, (struct sockaddr*)&addr, sizeof(addr)) == cwSOCKET_SYS_ERR )
{
if( cwIsNotFlag(s->createFlags, kBlockingFl) && errno == EINPROGRESS )
{
// if the socket is non-blocking the connection will complete asynchronously
}
else
{
return cwLogSysError(kOpFailRC, errno, "Socket connect to %s:%i failed.", cwStringNullGuard(remoteAddr), remotePort );
}
}
s->flags = cwSetFlag(s->flags,kIsConnectedFl);
s->remoteSockAddr = addr;
return rc;
}
rc_t _setTimeOutMs( sock_t* s, unsigned timeOutMs )
{
rc_t rc = kOkRC;
struct timeval timeOut;
// set the socket time out
timeOut.tv_sec = timeOutMs/1000;
timeOut.tv_usec = (timeOutMs - (timeOut.tv_sec * 1000)) * 1000;
if( setsockopt( s->sockH, SOL_SOCKET, SO_RCVTIMEO, &timeOut, sizeof(timeOut) ) == cwSOCKET_SYS_ERR )
{
rc = cwLogSysError(kOpFailRC,errno, "Attempt to set the socket timeout failed." );
goto errLabel;
}
errLabel:
return rc;
}
rc_t _get_info( int sockH, unsigned char outBuf[6], struct sockaddr_in* addr, const char* interfaceName )
{
cw::rc_t rc = kOkRC;
struct ifreq ifr;
struct ifconf ifc;
char buf[1024];
ifc.ifc_len = sizeof(buf);
ifc.ifc_buf = buf;
if (ioctl(sockH, SIOCGIFCONF, &ifc) == -1)
{
rc = cwLogSysError(kOpFailRC,errno,"ioctl(SIOCGIFCONF) failed.");
return rc;
}
struct ifreq* it = ifc.ifc_req;
const struct ifreq* const end = it + (ifc.ifc_len / sizeof(struct ifreq));
for (; it != end; ++it)
{
if( strcmp(it->ifr_name,interfaceName ) == 0 )
{
strcpy(ifr.ifr_name, it->ifr_name);
if (ioctl(sockH, SIOCGIFFLAGS, &ifr) != 0)
{
rc = cwLogSysError(kOpFailRC,errno,"ioctl(SIOCGIFCONF) failed.");
}
else
{
if (! (ifr.ifr_flags & IFF_LOOPBACK))
{
// don't count loopback
if (ioctl(sockH, SIOCGIFHWADDR, &ifr) == 0)
{
memcpy(outBuf, ifr.ifr_hwaddr.sa_data, 6);
if( addr != nullptr && ioctl(sockH, SIOCGIFADDR, &ifr) == 0)
{
addr->sin_addr = ((struct sockaddr_in *)&ifr.ifr_addr)->sin_addr;
}
return kOkRC;
}
}
}
}
}
return cwLogError(kInvalidArgRC,"The network interface information for '%s' could not be found.", interfaceName);
}
}
}
cw::rc_t cw::sock::createMgr( handle_t& hRef, unsigned recvBufByteN, unsigned maxSockN )
{
rc_t rc;
if((rc = destroyMgr(hRef)) != kOkRC )
return rc;
mgr_t* p = mem::allocZ<mgr_t>();
p->buf = mem::allocZ<uint8_t>(recvBufByteN);
p->bufByteN = recvBufByteN;
p->sockA = mem::allocZ<sock_t>( maxSockN );
p->pollfdA = mem::allocZ<struct pollfd>( maxSockN );
p->sockMaxN = maxSockN;
for(unsigned i=0; i<p->sockMaxN; ++i)
{
p->sockA[i].sockH = cwSOCKET_NULL_SOCK;
p->sockA[i].remoteSockAddr.sin_family = AF_UNSPEC;
p->sockA[i].pollfd = p->pollfdA + i;
}
hRef.set(p);
return rc;
}
cw::rc_t cw::sock::destroyMgr( handle_t& hRef )
{
rc_t rc = kOkRC;
if( ! hRef.isValid() )
return rc;
mgr_t* p = _handleToPtr(hRef);
if((rc = _destroyMgr(p)) != kOkRC )
return rc;
hRef.clear();
return rc;
}
cw::rc_t cw::sock::create( handle_t h,
unsigned userId,
short port,
unsigned flags,
unsigned timeOutMs,
callbackFunc_t cbFunc,
void* cbArg,
const char* remoteAddr,
portNumber_t remotePort,
const char* localAddr )
{
rc_t rc = kOkRC;
mgr_t* p;
sock_t* s;
// if a userId is being reused
_getMgrAndSocket(h, userId, p, s, false );
if( s != nullptr )
if((rc = _closeSock(p,s)) != kOkRC )
return kInvalidArgRC;
// if userId did not identify an existing socket ...
if( s == nullptr )
{
unsigned sockIdx;
// ... then find an available socket record
if((rc = _locateAvailSlot(p, sockIdx )) != kOkRC )
return rc;
s = p->sockA + sockIdx;
}
int type = cwIsFlag(flags,kStreamFl) ? SOCK_STREAM : SOCK_DGRAM;
int protocol = cwIsFlag(flags,kTcpFl) ? 0 : IPPROTO_UDP;
// get a handle to the socket
if(( s->sockH = ::socket( AF_INET, type, protocol ) ) == cwSOCKET_SYS_ERR )
return cwLogSysError(kOpFailRC, errno, "Socket create failed." );
s->userId = userId;
s->connId = kInvalidId;
s->createFlags = flags;
s->flags = 0;
s->cbFunc = cbFunc;
s->cbArg = cbArg;
s->pollfd = p->pollfdA + (s - p->sockA);
s->pollfd->events = POLLIN;
s->pollfd->fd = s->sockH;
s->nextConnId = 0;
// if this socket should block
if( cwIsFlag(flags,kBlockingFl))
{
if( timeOutMs > 0 )
{
_setTimeOutMs(s,timeOutMs);
}
s->flags = cwSetFlag(s->flags,kIsBlockingFl);
}
else // otherwise this is a non-blocking socket
{
int opts;
// get the socket options flags
if( (opts = fcntl(s->sockH,F_GETFL)) < 0 )
{
rc = cwLogSysError(kOpFailRC,errno, "Attempt to get the socket options flags failed." );
goto errLabel;
}
opts = (opts | O_NONBLOCK);
// set the socket options flags
if(fcntl(s->sockH,F_SETFL,opts) < 0)
{
rc = cwLogSysError(kOpFailRC,errno, "Attempt to set the socket to non-blocking failed." );
goto errLabel;
}
}
if( cwIsFlag(flags,kReuseAddrFl) )
{
unsigned int reuseaddr = 1;
if( setsockopt(s->sockH, SOL_SOCKET, SO_REUSEADDR, (const char*)&reuseaddr, sizeof(reuseaddr)) == cwSOCKET_SYS_ERR )
{
rc = cwLogSysError(kOpFailRC,errno, "Attempt to set the socket 'reuse address' attribute failed." );
goto errLabel;
}
}
#ifdef SO_REUSEPORT
if( cwIsFlag(flags,kReusePortFl) )
{
unsigned int reuseaddr = 1;
if(setsockopt(s->sockH, SOL_SOCKET, SO_REUSEPORT, (const char*)&reuseaddr, sizeof(reuseaddr)) == cwSOCKET_SYS_ERR )
{
rc = cwLogSysError(kOpFailRC,errno, "Attempt to set the socket 'reuse port' attribute failed." );
goto errLabel;
}
}
#endif
if( cwIsFlag(flags,kMultiCastTtlFl) )
{
unsigned char ttl = 1;
if( setsockopt(s->sockH, IPPROTO_IP, IP_MULTICAST_TTL, (const char*)&ttl, sizeof(ttl)) == cwSOCKET_SYS_ERR )
{
rc = cwLogSysError(kOpFailRC,errno, "Attempt to set the socket 'multicast TTL' attribute failed." );
goto errLabel;
}
}
if( cwIsFlag(flags,kMultiCastLoopFl) )
{
unsigned char loopback = 1;
if( setsockopt(s->sockH, IPPROTO_IP, IP_MULTICAST_LOOP, (const char*)&loopback, sizeof(loopback)) == cwSOCKET_SYS_ERR )
{
rc = cwLogSysError(kOpFailRC,errno, "Attempt to set the socket 'reuse port' attribute failed." );
goto errLabel;
}
}
// if broadcast option was requested.
if( cwIsFlag(flags,kBroadcastFl) )
{
int bcastFl = 1;
if( setsockopt( s->sockH, SOL_SOCKET, SO_BROADCAST, &bcastFl, sizeof(bcastFl) ) == cwSOCKET_SYS_ERR )
{
rc = cwLogSysError(kOpFailRC,errno, "Attempt to set the socket broadcast attribute failed." );
goto errLabel;
}
}
// create the 32 bit local address
if((rc = _initAddr( localAddr, port, &s->localSockAddr )) != kOkRC )
goto errLabel;
// bind the socket to a local address/port
if( (bind( s->sockH, (struct sockaddr*)&s->localSockAddr, sizeof(s->localSockAddr))) == cwSOCKET_SYS_ERR )
{
rc = cwLogSysError(kOpFailRC,errno,"Socket bind failed." );
goto errLabel;
}
// get the local address as a string
if((rc = addrToString( &s->localSockAddr, s->ntopBuf, sizeof(s->ntopBuf) )) != kOkRC )
goto errLabel;
// if a remote addr was given connect this socket to it
if( remoteAddr != nullptr )
if((rc = _connect(s,remoteAddr,remotePort)) != kOkRC )
goto errLabel;
// if the socket should be marked for listening
if( cwIsFlag(flags,kListenFl) )
{
if( ::listen(s->sockH, 10) != 0 )
{
rc = cwLogSysError(kOpFailRC,errno,"Socket listen() failed.");
goto errLabel;
}
}
errLabel:
if(rc != kOkRC )
_closeSock(p,s);
return rc;
}
cw::rc_t cw::sock::destroy( handle_t h, unsigned userId )
{
rc_t rc = kOkRC;
mgr_t* p;
sock_t* s;
if((rc = _getMgrAndSocket(h, userId, p, s )) != kOkRC )
return rc;
if((rc = _closeSock(p,s)) != kOkRC )
return rc;
return rc;
}
cw::rc_t cw::sock::set_multicast_time_to_live( handle_t h, unsigned userId, unsigned seconds )
{
rc_t rc = kOkRC;
mgr_t* p;
sock_t* s;
if((rc = _getMgrAndSocket(h, userId, p, s )) != kOkRC )
return rc;
if( setsockopt( s->sockH, IPPROTO_IP, IP_MULTICAST_TTL, &seconds, sizeof(seconds) ) == cwSOCKET_SYS_ERR )
{
rc = cwLogSysError(kOpFailRC,errno, "Attempt to set the socket multicast TTLfailed." );
}
return rc;
}
cw::rc_t cw::sock::join_multicast_group( handle_t h, unsigned userId, const char* addrStr )
{
rc_t rc = kOkRC;
mgr_t* p;
struct ip_mreq req;
sock_t* s;
memset(&req, 0, sizeof(req));
if((rc = _getMgrAndSocket(h, userId, p, s )) != kOkRC )
return rc;
if(inet_pton(AF_INET,addrStr,&req.imr_multiaddr.s_addr) == 0 )
{
rc = cwLogSysError(kOpFailRC,errno, "The network address string '%s' could not be converted to a netword address structure.",cwStringNullGuard(addrStr) );
goto errLabel;
}
req.imr_interface.s_addr = INADDR_ANY;
if(setsockopt(s->sockH, IPPROTO_IP, IP_ADD_MEMBERSHIP, (char*)&req, sizeof(req)) == cwSOCKET_SYS_ERR )
{
rc = cwLogSysError(kOpFailRC,errno, "Attempt to add socket to multicast group on '%s' failed.", cwStringNullGuard(addrStr) );
goto errLabel;
}
errLabel:
return rc;
}
// Set a destination address for this socket. Once a destination address is set
// the caller may use send() to communicate with the specified remote socket
// without having to specify a destination address on each call.
cw::rc_t cw::sock::connect( handle_t h, unsigned userId, const char* remoteAddr, portNumber_t remotePort )
{
rc_t rc = kOkRC;
mgr_t* p;
sock_t* s;
if((rc = _getMgrAndSocket(h, userId, p, s )) != kOkRC )
return rc;
return _connect(s,remoteAddr,remotePort);
}
bool cw::sock::isConnected( handle_t h, unsigned userId )
{
rc_t rc = kOkRC;
mgr_t* p;
sock_t* s;
if((rc = _getMgrAndSocket(h, userId, p, s )) != kOkRC )
return false;
return cwIsFlag(s->flags,kIsConnectedFl);
}
cw::rc_t cw::sock::send( handle_t h, unsigned userId, unsigned connId, const void* data, unsigned dataByteCnt )
{
rc_t rc = kOkRC;
mgr_t* p;
sock_t* s;
// locate the socket to send on
if((rc = _getMgrAndSocket(h, userId, p, s )) != kOkRC )
return rc;
// If this a pre-connected socket ...
if( cwIsFlag(s->flags,kIsConnectedFl) )
{
if( ::send( s->sockH, data, dataByteCnt, 0 ) == cwSOCKET_SYS_ERR )
rc = cwLogSysError(kOpFailRC,errno,"Send failed.");
}
else // ... otherwise this is a listening socket with one or more child sockets
{
if( s->children == nullptr )
return cwLogError(kInvalidOpRC,"socket::send() only works with connected sockets.");
sock_t* cs = s->children;
for(; cs != nullptr; cs=cs->children)
if( connId==kInvalidId || cs->connId == connId )
{
errno = 0;
if( ::send( cs->sockH, data, dataByteCnt, 0 ) == cwSOCKET_SYS_ERR )
rc = cwLogSysError(kOpFailRC,errno,"Send failed.");
if( cs->connId == connId )
break;
}
}
return rc;
}
cw::rc_t cw::sock::send( handle_t h, unsigned userId, const void* data, unsigned dataByteCnt, const struct sockaddr_in* remoteAddr )
{
rc_t rc = kOkRC;
mgr_t* p;
sock_t* s;
if((rc = _getMgrAndSocket(h, userId, p, s )) != kOkRC )
return rc;
errno = 0;
if( ::sendto(s->sockH, data, dataByteCnt, 0, (struct sockaddr*)remoteAddr, sizeof(*remoteAddr)) == cwSOCKET_SYS_ERR )
return cwLogSysError(kOpFailRC,errno,"Send to remote addr. failed.");
return kOkRC;
}
cw::rc_t cw::sock::send( handle_t h, unsigned userId, const void* data, unsigned dataByteCnt, const char* remoteAddr, portNumber_t remotePort )
{
rc_t rc = kOkRC;
mgr_t* p;
sock_t* s;
struct sockaddr_in addr;
if((rc = _getMgrAndSocket(h, userId, p, s )) != kOkRC )
return rc;
if((rc = _initAddr(remoteAddr,remotePort,&addr)) != kOkRC )
return rc;
return send( h, userId, data, dataByteCnt, &addr );
}
cw::rc_t cw::sock::receive_all( handle_t h, unsigned timeOutMs, unsigned& readByteN_Ref )
{
rc_t rc = kOkRC;
mgr_t* p = _handleToPtr(h);
if((rc = _poll( p, timeOutMs, readByteN_Ref )) != kOkRC && rc != kTimeOutRC )
return cwLogError(rc,"Socket receive failed.");
return rc;
}
cw::rc_t cw::sock::receive(handle_t h, unsigned userId, unsigned& readByteN_Ref, void* buf, unsigned bufByteN, struct sockaddr_in* fromAddr )
{
rc_t rc = kOkRC;
mgr_t* p;
sock_t* s;
if((rc = _getMgrAndSocket(h, userId, p, s )) != kOkRC )
return rc;
if((rc = _receive( p, s, readByteN_Ref, buf, bufByteN, fromAddr )) != kOkRC )
return rc;
return rc;
}
cw::rc_t cw::sock::get_mac( handle_t h, unsigned userId, unsigned char outBuf[6], struct sockaddr_in* addr, const char* netInterfaceName )
{
mgr_t* p;
sock_t* s;
rc_t rc;
if((rc = _getMgrAndSocket(h, userId, p, s )) != kOkRC )
return rc;
return _get_info(s->sockH, outBuf, addr, netInterfaceName );
}
cw::rc_t cw::sock::initAddr( const char* addrStr, portNumber_t portNumber, struct sockaddr_in* retAddrPtr )
{
return _initAddr(addrStr,portNumber,retAddrPtr);
}
cw::rc_t cw::sock::addrToString( const struct sockaddr_in* addr, char* buf, unsigned bufN )
{
rc_t rc = kOkRC;
errno = 0;
if( inet_ntop(AF_INET, &(addr->sin_addr), buf, bufN) == nullptr)
{
rc = cwLogSysError(kOpFailRC,errno, "Network address to string conversion failed." );
goto errLabel;
}
buf[bufN-1]=0;
errLabel:
return rc;
}
bool cw::sock::addrIsEqual( const struct sockaddr_in* a0, const struct sockaddr_in* a1 )
{
return a0->sin_family == a1->sin_family
&& a0->sin_port == a1->sin_port
&& memcmp(&a0->sin_addr,&a1->sin_addr,sizeof(a0->sin_addr))==0;
}
const char* cw::sock::hostName( handle_t h, unsigned userId )
{
rc_t rc = kOkRC;
mgr_t* p;
sock_t* s;
if((rc = _getMgrAndSocket(h, userId, p, s )) != kOkRC )
return nullptr;
errno = 0;
if( gethostname(s->hnameBuf,HOST_NAME_MAX) != 0 )
{
cwLogSysError(kOpFailRC,errno, "gethostname() failed." );
return nullptr;
}
s->hnameBuf[HOST_NAME_MAX] = 0;
return s->hnameBuf;
}
const char* cw::sock::ipAddress( handle_t h, unsigned userId )
{
rc_t rc = kOkRC;
mgr_t* p;
sock_t* s;
if((rc = _getMgrAndSocket(h, userId, p, s )) != kOkRC )
return nullptr;
return s->ntopBuf;
}
unsigned cw::sock::inetAddress( handle_t h, unsigned userId )
{
rc_t rc = kOkRC;
mgr_t* p;
sock_t* s;
if((rc = _getMgrAndSocket(h, userId, p, s )) != kOkRC )
return 0;
return s->localSockAddr.sin_addr.s_addr;
}
cw::sock::portNumber_t cw::sock::port( handle_t h, unsigned userId )
{
rc_t rc = kOkRC;
mgr_t* p;
sock_t* s;
if((rc = _getMgrAndSocket(h, userId, p, s )) != kOkRC )
return rc;
return ntohs(s->localSockAddr.sin_port);
}
cw::rc_t cw::sock::peername( handle_t h, unsigned userId, struct sockaddr_in* addr )
{
rc_t rc = kOkRC;
socklen_t n = sizeof(struct sockaddr_in);
mgr_t* p;
sock_t* s;
if((rc = _getMgrAndSocket(h, userId, p, s )) != kOkRC )
return rc;
if( getpeername(s->sockH, (struct sockaddr*)addr, &n) == cwSOCKET_SYS_ERR )
return cwLogSysError(kOpFailRC,errno,"Get peer name failed.");
addr->sin_port = ntohs(addr->sin_port);
return rc;
}
cw::rc_t cw::sock::get_info( const char* netInterfaceName, unsigned char mac[6], char* host, unsigned hostN, struct sockaddr_in* addr )
{
rc_t rc = kOkRC;
int sockH;
if( host != nullptr )
if( gethostname(host,hostN) != 0 )
return cwLogSysError(kOpFailRC,errno,"Unable to get the local host name.");
// get a handle to the socket
if(( sockH = ::socket( AF_INET, SOCK_DGRAM, 0 ) ) == cwSOCKET_SYS_ERR )
return cwLogSysError(kOpFailRC,errno,"Unable to create temporary socket.");
if((rc = _get_info(sockH,mac,addr,netInterfaceName)) != kOkRC )
goto errLabel;
errLabel:
close(sockH);
return rc;
}
//===============================================================================================
namespace cw
{
namespace socksrv
{
typedef struct socksrv_str
{
sock::handle_t sockMgrH;
thread::handle_t thH;
unsigned timeOutMs;
} socksrv_t;
socksrv_t* _handleToPtr( handle_t h )
{
return handleToPtr<handle_t,socksrv_t>(h);
}
rc_t _destroyMgrSrv( socksrv_t* p )
{
rc_t rc = kOkRC;
// destroy the thread
if((rc = destroy(p->thH)) != kOkRC )
return rc;
// destroy the socket manager
if((rc = sock::destroyMgr(p->sockMgrH)) != kOkRC )
goto errLabel;
mem::release(p);
errLabel:
return rc;
}
bool _threadFunc( void* arg )
{
socksrv_t* p = (socksrv_t*)arg;
unsigned readByteN = 0;
rc_t rc;
//
if((rc = sock::receive_all( p->sockMgrH, p->timeOutMs, readByteN)) != kOkRC && rc != kTimeOutRC )
{
cwLogError(rc,"Socket Srv receive failed.");
return false;
}
return true;
}
// Callback thread used by socksrv::test() below
void _socketTestCbFunc( void* cbArg, sock::cbOpId_t cbId, unsigned userId, unsigned connId, const void* byteA, unsigned byteN, const struct sockaddr_in* srcAddr )
{
rc_t rc;
char addr[ INET_ADDRSTRLEN+1 ];
printf("type:%i user:%i conn:%i ", cbId, userId, connId );
if( srcAddr != nullptr )
if((rc = sock::addrToString( srcAddr, addr, INET_ADDRSTRLEN )) == kOkRC )
{
printf("from %s ", addr );
}
if( byteA != nullptr )
printf(" : %s ", (const char*)byteA);
printf("\n");
}
}
}
cw::rc_t cw::socksrv::createMgrSrv( handle_t& hRef, unsigned timeOutMs, unsigned recvBufByteN, unsigned maxSocketN )
{
cw::rc_t rc = kOkRC;
if((rc = destroyMgrSrv(hRef)) != kOkRC )
return rc;
// allocate the object
socksrv_t* p = mem::allocZ<socksrv_t>();
// create the socket manager
if((rc = createMgr( p->sockMgrH, recvBufByteN, maxSocketN )) != kOkRC )
goto errLabel;
// create the thread
if((rc = thread::create( p->thH, _threadFunc, p)) != kOkRC )
goto errLabel;
p->timeOutMs = timeOutMs;
hRef.set(p);
errLabel:
return rc;
}
cw::rc_t cw::socksrv::destroyMgrSrv( handle_t& hRef )
{
rc_t rc = kOkRC;
if( !hRef.isValid() )
return kOkRC;
socksrv_t* p = _handleToPtr(hRef);
if((rc = _destroyMgrSrv(p)) != kOkRC )
return rc;
hRef.clear();
return rc;
}
cw::sock::handle_t cw::socksrv::mgrHandle( handle_t h )
{
socksrv_t* p = _handleToPtr(h);
return p->sockMgrH;
}
cw::rc_t cw::socksrv::start( handle_t h )
{
socksrv_t* p = _handleToPtr(h);
return thread::unpause( p->thH );
}
cw::rc_t cw::socksrv::stop( handle_t h )
{
socksrv_t* p = _handleToPtr(h);
return thread::pause( p->thH );
}
cw::rc_t cw::socksrv::test( const char* localNicDevice, sock::portNumber_t localPort, const char* remoteAddrIp, sock::portNumber_t remotePort, unsigned flags )
{
handle_t h;
rc_t rc = kOkRC;
unsigned timeOutMs = 50;
unsigned recvBufByteN = 2048;
unsigned maxSocketN = 10;
unsigned userId = 10;
unsigned sockFlags = sock::kNonBlockingFl | flags;
bool serverFl = remoteAddrIp == nullptr;
const char* localIpAddrPtr = nullptr;
char localIpAddr[ INET_ADDRSTRLEN+1 ];
const unsigned sbufN = 31;
char sbuf[ sbufN+1 ];
// if a local device was given
if( localNicDevice != nullptr )
{
struct sockaddr_in localAddr;
unsigned char mac[6];
// get the IP address of the device
if((rc = sock::get_info(localNicDevice, mac, nullptr, 0, &localAddr )) != kOkRC )
return cwLogError(rc,"Unable to obtain the local address information for the device:'%s'.",localNicDevice);
// convert the IP address to a string
if((rc = sock::addrToString( &localAddr, localIpAddr, INET_ADDRSTRLEN )) != kOkRC )
return cwLogError(rc,"Unable to convert the local address to a string for device:'%s'.",localNicDevice);
localIpAddrPtr = localIpAddr;
}
if( serverFl )
printf("Server listening on %s port: %i\n", localIpAddrPtr==nullptr ? "" : localIpAddrPtr, localPort );
else
printf("Client connecting to server %s:%i\n", remoteAddrIp,remotePort);
// create the socket manager
if((rc = createMgrSrv(h, timeOutMs, recvBufByteN, maxSocketN )) != kOkRC )
return cwLogError(rc,"Socket server create failed.");
// start the socket manager
if((rc = start(h)) != kOkRC )
{
cwLogError(rc,"Socker server start failed.");
goto errLabel;
}
// create a socket
if((rc = create( mgrHandle(h), userId, localPort, sockFlags, timeOutMs, _socketTestCbFunc, nullptr, remoteAddrIp, remotePort, localIpAddrPtr)) != kOkRC )
{
cwLogError(rc,"Socket server socket create failed.");
goto errLabel;
}
printf("'quit' to exit\n");
// readline loop
while( true )
{
printf("? ");
if( std::fgets(sbuf,sbufN,stdin) == sbuf )
{
printf("Sending:%s",sbuf);
// send a message to the remote socket
if( sock::send( mgrHandle(h), userId, -1, sbuf, strlen(sbuf)+1 ) != kOkRC )
printf("Send failed.");
if( strcmp(sbuf,"quit\n") == 0)
break;
}
}
errLabel:
rc_t rc1 = kOkRC;
// destroy the socket
if( h.isValid() )
rc1 = destroy( mgrHandle(h), userId );
// destroy the socket manager
rc_t rc2 = destroyMgrSrv(h);
return rcSelect(rc,rc1,rc2);
}
cw::rc_t cw::socksrv::testMain( bool tcpFl, const char* localNicDevice, sock::portNumber_t localPort, const char* remoteAddrIp, sock::portNumber_t remotePort )
{
unsigned flags = 0;
if( tcpFl )
{
flags |= sock::kTcpFl | sock::kStreamFl | sock::kReuseAddrFl | sock::kReusePortFl;
if( remoteAddrIp == nullptr )
flags |= sock::kListenFl;
}
return test(localNicDevice,localPort,remoteAddrIp,remotePort,flags);
}