//============================================================================= /** * @file INET_Addr_Test.cpp * * Performs several tests on the ACE_INET_Addr class. It creates several * IPv4 and IPv6 addresses and checks that the address formed by the * class is valid. * * @author John Aughey (jha@aughey.com) */ //============================================================================= #include "test_config.h" #include "ace/OS_NS_string.h" #include "ace/INET_Addr.h" #include "ace/Log_Msg.h" #include "ace/OS_NS_arpa_inet.h" #include "ace/SString.h" #include "ace/OS_NS_unistd.h" // Make sure that ACE_Addr::addr_type_ is the same // as the family of the inet_addr_. static int check_type_consistency (const ACE_INET_Addr &addr) { int family = -1; if (addr.get_type () == AF_INET) { struct sockaddr_in *sa4 = (struct sockaddr_in *)addr.get_addr(); family = sa4->sin_family; } #if defined (ACE_HAS_IPV6) else if (addr.get_type () == AF_INET6) { struct sockaddr_in6 *sa6 = (struct sockaddr_in6 *)addr.get_addr(); family = sa6->sin6_family; } #endif if (addr.get_type () != family) { ACE_ERROR ((LM_ERROR, ACE_TEXT ("Inconsistency between ACE_SOCK::addr_type_ (%d) ") ACE_TEXT ("and the sockaddr family (%d)\n"), addr.get_type (), family)); return 1; } return 0; } static bool test_tao_use () { char host[256]; if (::gethostname (host, 255) != 0) { ACE_ERROR ((LM_ERROR, ACE_TEXT ("Test TAO Use fail %p\n"), ACE_TEXT ("gethostname"))); return false; } ACE_INET_Addr addr; addr.set ((unsigned short)0, host); ACE_CString full (host); full += ":12345"; addr.set (full.c_str ()); u_short p = addr.get_port_number (); if (p != 12345) { ACE_ERROR ((LM_ERROR, ACE_TEXT ("Test TAO Use expected port 12345 got %d\n"), p)); return false; } ACE_DEBUG ((LM_DEBUG, ACE_TEXT ("Test TAO Use passed\n"))); return true; } static bool test_port_assignment () { #if defined (ACE_HAS_IPV6) ACE_INET_Addr addr1 (static_cast (0), ACE_IPV6_ANY, AF_INET6); ACE_INET_Addr addr2; addr1.set_port_number (12345); addr2.set (addr1); if (addr1.get_port_number () != addr2.get_port_number ()) { ACE_ERROR ((LM_ERROR, ACE_TEXT ("port number not properly copied. ") ACE_TEXT ("addr1 port = %d addr2 port = %d\n"), addr1.get_port_number (), addr2.get_port_number ())); return false; } ACE_DEBUG ((LM_DEBUG, ACE_TEXT ("Test Port Assignment passed\n"))); #else ACE_DEBUG ((LM_DEBUG, ACE_TEXT ("Test Port Assignment is IPv6 only\n"))); #endif /* ACE_HAS_IPV6 */ return true; } static bool test_multiple () { bool success = true; // Check the behavior when there are multiple addresses assigned to a name. // The NTP pool should always return multiples, though always different. ACE_INET_Addr ntp; if (ntp.set (123, ACE_TEXT ("pool.ntp.org")) == -1) { // This is just a warning to prevent fails on lookups on hosts with no // DNS service. The real value of this test is to accurately get // multiples from the result. ACE_ERROR ((LM_WARNING, ACE_TEXT ("%p\n"), ACE_TEXT ("pool.ntp.org"))); return true; } size_t count = 0; ACE_TCHAR addr_string[256]; do { ++count; // If lookup succeeded, there's at least one ntp.addr_to_string (addr_string, sizeof (addr_string)); ACE_DEBUG ((LM_DEBUG, ACE_TEXT ("IPv4 %B: %s\n"), count, addr_string)); } while (ntp.next ()); success = count > 1; #if defined (ACE_HAS_IPV6) ACE_INET_Addr ntp6; if (ntp6.set (123, ACE_TEXT ("2.pool.ntp.org"), 1, AF_INET6) == -1) { ACE_ERROR ((LM_ERROR, ACE_TEXT ("%p\n"), ACE_TEXT ("2.pool.ntp.org"))); return false; } count = 0; do { ++count; // If lookup succeeded, there's at least one ntp6.addr_to_string (addr_string, sizeof (addr_string)); ACE_DEBUG ((LM_DEBUG, ACE_TEXT ("IPv6 %B: %s\n"), count, addr_string)); } while (ntp6.next ()); if (count <= 1) success = false; #endif /* ACE_HAS_IPV6 */ return success; } struct Address { const char* name; bool loopback; }; int run_main (int, ACE_TCHAR *[]) { ACE_START_TEST (ACE_TEXT ("INET_Addr_Test")); int status = 0; // Innocent until proven guilty // Try to set up known IP and port. u_short port (80); ACE_UINT32 const ia_any = INADDR_ANY; ACE_INET_Addr local_addr(port, ia_any); status |= check_type_consistency (local_addr); if (local_addr.get_port_number () != 80) { ACE_ERROR ((LM_ERROR, ACE_TEXT ("Got port %d, expecting 80\n"), (int)(local_addr.get_port_number ()))); status = 1; } if (local_addr.get_ip_address () != ia_any) { ACE_ERROR ((LM_ERROR, ACE_TEXT ("Mismatch on local IP addr\n"))); status = 1; } // Assignment constructor ACE_INET_Addr local_addr2 (local_addr); status |= check_type_consistency (local_addr2); if (local_addr2.get_port_number () != 80) { ACE_ERROR ((LM_ERROR, ACE_TEXT ("Copy got port %d, expecting 80\n"), (int)(local_addr2.get_port_number ()))); status = 1; } if (local_addr2.get_ip_address () != ia_any) { ACE_ERROR ((LM_ERROR, ACE_TEXT ("Mismatch on copy local IP addr\n"))); status = 1; } if (local_addr != local_addr2) { ACE_ERROR ((LM_ERROR, ACE_TEXT ("Copy local addr mismatch\n"))); status = 1; } // Try to parse out a simple address:port string. Intentionally reuse // the ACE_INET_Addr to ensure resetting an address works. const char *addr_ports[] = { "127.0.0.1:80", "www.dre.vanderbilt.edu:80", 0 }; ACE_INET_Addr addr_port; for (int i = 0; addr_ports[i] != 0; ++i) { if (addr_port.set (addr_ports[i]) == 0) { status |= check_type_consistency (addr_port); if (addr_port.get_port_number () != 80) { ACE_ERROR ((LM_ERROR, ACE_TEXT ("Got port %d from %s\n"), (int)(addr_port.get_port_number ()), addr_ports[i])); status = 1; } ACE_INET_Addr check (addr_ports[i]); if (addr_port != check) { ACE_ERROR ((LM_ERROR, ACE_TEXT ("Reset on iter %d failed\n"), i)); if (addr_port.get_type() != check.get_type()) { ACE_ERROR ((LM_ERROR, ACE_TEXT (" addr_port.get_type()= %d, check.get_type()=%d\n") , addr_port.get_type(), check.get_type())); } if (addr_port.get_size() != check.get_size()) { ACE_ERROR ((LM_ERROR, ACE_TEXT (" addr_port.get_size()= %d, check.get_size()=%d\n") , addr_port.get_size(), check.get_size())); } #if defined(ACE_HAS_IPV6) if (addr_port.get_type() == check.get_type() && addr_port.get_size() == check.get_size()){ if (addr_port.get_type() == AF_INET6) { const struct sockaddr_in6 *addr_port_in6 = static_cast (addr_port.get_addr()); const struct sockaddr_in6 *check_in6 = static_cast (check.get_addr()); # if defined(AIX) ACE_ERROR((LM_ERROR, ACE_TEXT (" addr_port_in6->sin6_len=%d, check_in6->sin6_len=%d\n") , (int)addr_port_in6->sin6_len, (int)check_in6->sin6_len)); # endif ACE_ERROR((LM_ERROR, ACE_TEXT (" addr_port_in6->sin6_family=%d, check_in6->sin6_family=%d\n") , (int)addr_port_in6->sin6_family, (int)check_in6->sin6_family)); ACE_ERROR((LM_ERROR, ACE_TEXT (" addr_port_in6->sin6_port=%d, check_in6->sin6_port=%d\n") , (int)addr_port_in6->sin6_port, (int)check_in6->sin6_port)); ACE_ERROR((LM_ERROR, ACE_TEXT (" addr_port_in6->sin6_flowinfo=%d, check_in6->sin6_flowinfo=%d\n") , (int)addr_port_in6->sin6_flowinfo, (int)check_in6->sin6_flowinfo)); ACE_ERROR((LM_ERROR, ACE_TEXT (" addr_port_in6->sin6_scope_id=%d, check_in6->sin6_scope_id=%d\n") , (int)addr_port_in6->sin6_scope_id, (int)check_in6->sin6_scope_id)); ACE_ERROR((LM_DEBUG, ACE_TEXT (" addr_port_in6->sin6_addr="))); ACE_HEX_DUMP((LM_DEBUG, reinterpret_cast(&addr_port_in6->sin6_addr), sizeof(addr_port_in6->sin6_addr))); ACE_ERROR((LM_DEBUG, ACE_TEXT (" check_in6->sin6_addr="))); ACE_HEX_DUMP((LM_DEBUG, reinterpret_cast(&check_in6->sin6_addr), sizeof(check_in6->sin6_addr))); } } #endif status = 1; } } else { // Sometimes this fails because the run-time host lacks the capability to // resolve a name. But it shouldn't fail on the first one, 127.0.0.1. if (i == 0) { ACE_ERROR ((LM_ERROR, ACE_TEXT ("%C: %p\n"), addr_ports[i], ACE_TEXT ("lookup"))); status = 1; } else { ACE_ERROR ((LM_WARNING, ACE_TEXT ("%C: %p\n"), addr_ports[i], ACE_TEXT ("lookup"))); } } } const char *ipv4_addresses[] = { "127.0.0.1", "138.38.180.251", "64.219.54.121", "192.0.0.1", "10.0.0.1", 0 }; ACE_INET_Addr addr; status |= check_type_consistency (addr); char hostaddr[1024]; for (int i=0; ipv4_addresses[i] != 0; i++) { struct in_addr addrv4; ACE_OS::memset ((void *) &addrv4, 0, sizeof addrv4); ACE_UINT32 addr32; ACE_OS::inet_pton (AF_INET, ipv4_addresses[i], &addrv4); ACE_OS::memcpy (&addr32, &addrv4, sizeof (addr32)); status |= !(addr.set (80, ipv4_addresses[i]) == 0); status |= check_type_consistency (addr); /* ** Now check to make sure get_ip_address matches and get_host_addr ** matches. */ if (addr.get_ip_address () != ACE_HTONL (addr32)) { ACE_ERROR ((LM_ERROR, ACE_TEXT ("Error: %C failed get_ip_address() check\n") ACE_TEXT ("0x%x != 0x%x\n"), ipv4_addresses[i], addr.get_ip_address (), ACE_HTONL (addr32))); status = 1; } if (addr.get_host_addr () != 0 && ACE_OS::strcmp (addr.get_host_addr(), ipv4_addresses[i]) != 0) { ACE_ERROR ((LM_ERROR, ACE_TEXT ("%C failed get_host_addr() check\n") ACE_TEXT ("%C != %C\n"), ipv4_addresses[i], addr.get_host_addr (), ipv4_addresses[i])); status = 1; } // Now we check the operation of get_host_addr(char*,int) const char* haddr = addr.get_host_addr (&hostaddr[0], sizeof(hostaddr)); if (haddr != 0 && ACE_OS::strcmp (&hostaddr[0], haddr) != 0) { ACE_ERROR ((LM_ERROR, ACE_TEXT ("%C failed get_host_addr(char* buf,int) check\n") ACE_TEXT ("buf ['%C'] != return value ['%C']\n"), ipv4_addresses[i], &hostaddr[0], haddr)); status = 1; } if (ACE_OS::strcmp (&hostaddr[0], ipv4_addresses[i]) != 0) { ACE_ERROR ((LM_ERROR, ACE_TEXT ("%C failed get_host_addr(char*,int) check\n") ACE_TEXT ("buf ['%C'] != expected value ['%C']\n"), ipv4_addresses[i], &hostaddr[0], ipv4_addresses[i])); status = 1; } // Clear out the address by setting it to 1 and check addr.set (0, ACE_UINT32 (1), 1); status |= check_type_consistency (addr); if (addr.get_ip_address () != 1) { ACE_ERROR ((LM_ERROR, ACE_TEXT ("Failed to set address to 1\n"))); status = 1; } // Now set the address using a 32 bit number and check that we get // the right string out of get_host_addr(). addr.set (80, addr32, 0); // addr32 is already in network byte order status |= check_type_consistency(addr); if (addr.get_host_addr () != 0 && ACE_OS::strcmp (addr.get_host_addr (), ipv4_addresses[i]) != 0) { ACE_ERROR ((LM_ERROR, ACE_TEXT ("%C failed second get_host_addr() check\n") ACE_TEXT ("return value ['%C'] != expected value ['%C']\n"), ipv4_addresses[i], addr.get_host_addr (), ipv4_addresses[i])); status = 1; } // Test for ACE_INET_Addr::set_addr(). struct sockaddr_in sa4; sa4.sin_family = AF_INET; sa4.sin_addr = addrv4; sa4.sin_port = ACE_HTONS (8080); addr.set (0, ACE_UINT32 (1), 1); addr.set_addr (&sa4, sizeof(sa4)); status |= check_type_consistency (addr); if (addr.get_port_number () != 8080) { ACE_ERROR ((LM_ERROR, ACE_TEXT ("ACE_INET_Addr::set_addr() ") ACE_TEXT ("failed to update port number.\n"))); status = 1; } if (addr.get_ip_address () != ACE_HTONL (addr32)) { ACE_ERROR ((LM_ERROR, ACE_TEXT ("ACE_INET_Addr::set_addr() ") ACE_TEXT ("failed to update address.\n"))); status = 1; } } #if defined (ACE_HAS_IPV6) if (ACE::ipv6_enabled ()) { char local_host_name[1024]; ACE_OS::hostname(local_host_name, 1024); const char* local_names[] = {"localhost", local_host_name}; for (int i = 0; i < 2; ++i) { ACE_INET_Addr addr; int old_type = addr.get_type(); if (addr.set(12345, local_names[i]) == 0) { if (addr.get_type() != old_type) { ACE_ERROR ((LM_ERROR, ACE_TEXT ("IPv6 set failed: addr.set(12345, \"%C\"), old addr.type() = %d, new addr_type()= %d\n"), local_names[i], old_type, addr.get_type ())); status = 1; } } else { ACE_DEBUG ((LM_DEBUG, ACE_TEXT ("IPv6 set failed: addr.set(12345, \"%C\") returns nonzero\n"), local_names[i])); } } const char *ipv6_addresses[] = { "1080::8:800:200c:417a", // unicast address "ff01::101", // multicast address "::1", // loopback address "::", // unspecified addresses 0 }; for (int i=0; ipv6_addresses[i] != 0; i++) { ACE_INET_Addr addr (80, ipv6_addresses[i]); status |= check_type_consistency (addr); if (0 != ACE_OS::strcmp (addr.get_host_addr (), ipv6_addresses[i])) { ACE_ERROR ((LM_ERROR, ACE_TEXT ("IPv6 get_host_addr failed: %C != %C\n"), addr.get_host_addr (), ipv6_addresses[i])); status = 1; } } const char *ipv6_names[] = { "naboo.dre.vanderbilt.edu", "v6.ipv6-test.com", 0 }; for (int i=0; ipv6_names[i] != 0; i++) { ACE_INET_Addr addr (80, ipv6_names[i]); status |= check_type_consistency (addr); if (0 != ACE_OS::strcmp (addr.get_host_name (), ipv6_names[i])) { // Alias? Check lookup on the reverse. ACE_INET_Addr alias_check; if (alias_check.set (80, addr.get_host_name ()) == 0) { if (addr != alias_check) ACE_ERROR ((LM_WARNING, ACE_TEXT ("IPv6 name mismatch: %s (%s) != %s\n"), addr.get_host_name (), addr.get_host_addr (), ipv6_names[i])); } else { ACE_ERROR ((LM_WARNING, ACE_TEXT ("IPv6 reverse lookup mismatch: %s (%s) != %s\n"), addr.get_host_name (), addr.get_host_addr (), ipv6_names[i])); } } } } ACE_DEBUG ((LM_DEBUG, ACE_TEXT ("IPv6 tests done\n"))); #else ACE_DEBUG ((LM_DEBUG, ACE_TEXT ("ACE_HAS_IPV6 not set; no IPv6 tests run\n"))); #endif struct Address loopback_addresses[] = { {"127.0.0.1", true}, {"127.1.2.3", true} , {"127.0.0.0", true}, {"127.255.255.255", true} , {"126.255.255.255", false}, {"128.0.0.0", false}, {0, true} }; for (int i=0; loopback_addresses[i].name != 0; i++) { struct in_addr addrv4; ACE_UINT32 addr32 = 0; ACE_OS::inet_pton (AF_INET, loopback_addresses[i].name, &addrv4); ACE_OS::memcpy (&addr32, &addrv4, sizeof (addr32)); addr.set (80, loopback_addresses[i].name); if (addr.is_loopback() != loopback_addresses[i].loopback) { ACE_ERROR ((LM_ERROR, ACE_TEXT ("ACE_INET_Addr::is_loopback() ") ACE_TEXT ("failed to distinguish loopback address. %C\n") , loopback_addresses[i].name)); status = 1; } } if (addr.string_to_addr ("127.0.0.1:72000", AF_INET) != -1) { ACE_ERROR ((LM_ERROR, ACE_TEXT ("ACE_INET_Addr::string_to_addr() ") ACE_TEXT ("failed to detect port number overflow\n"))); status = 1; } if (!test_tao_use ()) status = 1; if (!test_multiple ()) status = 1; if (!test_port_assignment ()) status = 1; ACE_INET_Addr a1 (80, "127.0.0.1"); ACE_INET_Addr a2 = a1; if (a1 != a2) { ACE_ERROR ((LM_ERROR, ACE_TEXT ("Address equality check failed after assignment\n"))); status = 1; } ACE_END_TEST; return status; }