KisChunk KisChunkAllocator::getChunk(quint64 size) { KisChunkDataListIterator startPosition = m_iterator; START_COUNTING(); forever { if(tryInsertChunk(m_list, m_iterator, size)) return WRAP_PREVIOUS_CHUNK_DATA(m_iterator); if(m_iterator == m_list.end()) break; m_iterator++; REGISTER_STEP(); } REGISTER_FAIL(); m_iterator = m_list.begin(); forever { if(tryInsertChunk(m_list, m_iterator, size)) return WRAP_PREVIOUS_CHUNK_DATA(m_iterator); if(m_iterator == m_list.end() || m_iterator == startPosition) break; m_iterator++; REGISTER_STEP(); } REGISTER_FAIL(); m_iterator = m_list.end(); while ((m_storeSize += m_storeSlabSize) <= m_storeMaxSize) { if(tryInsertChunk(m_list, m_iterator, size)) return WRAP_PREVIOUS_CHUNK_DATA(m_iterator); } qFatal("KisChunkAllocator: out of swap space"); // just let gcc be happy! :) return KisChunk(m_list.end()); }
void run_tests(void) { k_thread_priority_set(k_current_get(), K_PRIO_COOP(7)); test_failed = false; struct net_conn_handle *handlers[CONFIG_NET_MAX_CONN]; struct net_if *iface = net_if_get_default(); struct net_if_addr *ifaddr; struct ud *ud; int ret, i = 0; bool st; struct sockaddr_in6 any_addr6; const struct in6_addr in6addr_any = IN6ADDR_ANY_INIT; struct sockaddr_in6 my_addr6; struct in6_addr in6addr_my = { { { 0x20, 0x01, 0x0d, 0xb8, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0x1 } } }; struct sockaddr_in6 peer_addr6; struct in6_addr in6addr_peer = { { { 0x20, 0x01, 0x0d, 0xb8, 0, 0, 0, 0, 0, 0, 0, 0x4e, 0x11, 0, 0, 0x2 } } }; struct sockaddr_in any_addr4; const struct in_addr in4addr_any = { { { 0 } } }; struct sockaddr_in my_addr4; struct in_addr in4addr_my = { { { 192, 0, 2, 1 } } }; struct sockaddr_in peer_addr4; struct in_addr in4addr_peer = { { { 192, 0, 2, 9 } } }; net_ipaddr_copy(&any_addr6.sin6_addr, &in6addr_any); any_addr6.sin6_family = AF_INET6; net_ipaddr_copy(&my_addr6.sin6_addr, &in6addr_my); my_addr6.sin6_family = AF_INET6; net_ipaddr_copy(&peer_addr6.sin6_addr, &in6addr_peer); peer_addr6.sin6_family = AF_INET6; net_ipaddr_copy(&any_addr4.sin_addr, &in4addr_any); any_addr4.sin_family = AF_INET; net_ipaddr_copy(&my_addr4.sin_addr, &in4addr_my); my_addr4.sin_family = AF_INET; net_ipaddr_copy(&peer_addr4.sin_addr, &in4addr_peer); peer_addr4.sin_family = AF_INET; k_sem_init(&recv_lock, 0, UINT_MAX); ifaddr = net_if_ipv6_addr_add(iface, &in6addr_my, NET_ADDR_MANUAL, 0); if (!ifaddr) { printk("Cannot add %s to interface %p\n", net_sprint_ipv6_addr(&in6addr_my), iface); zassert_true(0, "exiting"); } ifaddr = net_if_ipv4_addr_add(iface, &in4addr_my, NET_ADDR_MANUAL, 0); if (!ifaddr) { printk("Cannot add %s to interface %p\n", net_sprint_ipv4_addr(&in4addr_my), iface); zassert_true(0, "exiting"); } #define REGISTER(family, raddr, laddr, rport, lport) \ ({ \ static struct ud user_data; \ \ user_data.remote_addr = (struct sockaddr *)raddr; \ user_data.local_addr = (struct sockaddr *)laddr; \ user_data.remote_port = rport; \ user_data.local_port = lport; \ user_data.test = "DST="#raddr"-SRC="#laddr"-RP="#rport \ "-LP="#lport; \ \ set_port(family, (struct sockaddr *)raddr, \ (struct sockaddr *)laddr, rport, lport); \ \ ret = net_udp_register((struct sockaddr *)raddr, \ (struct sockaddr *)laddr, \ rport, lport, \ test_ok, &user_data, \ &handlers[i]); \ if (ret) { \ printk("UDP register %s failed (%d)\n", \ user_data.test, ret); \ zassert_true(0, "exiting"); \ } \ user_data.handle = handlers[i++]; \ &user_data; \ }) #define REGISTER_FAIL(raddr, laddr, rport, lport) \ ret = net_udp_register((struct sockaddr *)raddr, \ (struct sockaddr *)laddr, \ rport, lport, \ test_fail, INT_TO_POINTER(0), NULL); \ if (!ret) { \ printk("UDP register invalid match %s failed\n", \ "DST="#raddr"-SRC="#laddr"-RP="#rport"-LP="#lport); \ zassert_true(0, "exiting"); \ } #define UNREGISTER(ud) \ ret = net_udp_unregister(ud->handle); \ if (ret) { \ printk("UDP unregister %p failed (%d)\n", ud->handle, \ ret); \ zassert_true(0, "exiting"); \ } #define TEST_IPV6_OK(ud, raddr, laddr, rport, lport) \ st = send_ipv6_udp_msg(iface, raddr, laddr, rport, lport, ud, \ false); \ if (!st) { \ printk("%d: UDP test \"%s\" fail\n", __LINE__, \ ud->test); \ zassert_true(0, "exiting"); \ } #define TEST_IPV6_LONG_OK(ud, raddr, laddr, rport, lport) \ st = send_ipv6_udp_long_msg(iface, raddr, laddr, rport, lport, ud, \ false); \ if (!st) { \ printk("%d: UDP long test \"%s\" fail\n", __LINE__, \ ud->test); \ zassert_true(0, "exiting"); \ } #define TEST_IPV4_OK(ud, raddr, laddr, rport, lport) \ st = send_ipv4_udp_msg(iface, raddr, laddr, rport, lport, ud, \ false); \ if (!st) { \ printk("%d: UDP test \"%s\" fail\n", __LINE__, \ ud->test); \ zassert_true(0, "exiting"); \ } #define TEST_IPV6_FAIL(ud, raddr, laddr, rport, lport) \ st = send_ipv6_udp_msg(iface, raddr, laddr, rport, lport, ud, \ true); \ if (!st) { \ printk("%d: UDP neg test \"%s\" fail\n", __LINE__, \ ud->test); \ zassert_true(0, "exiting"); \ } #define TEST_IPV4_FAIL(ud, raddr, laddr, rport, lport) \ st = send_ipv4_udp_msg(iface, raddr, laddr, rport, lport, ud, \ true); \ if (!st) { \ printk("%d: UDP neg test \"%s\" fail\n", __LINE__, \ ud->test); \ zassert_true(0, "exiting"); \ } ud = REGISTER(AF_INET6, &any_addr6, &any_addr6, 1234, 4242); TEST_IPV6_OK(ud, &in6addr_peer, &in6addr_my, 1234, 4242); TEST_IPV6_OK(ud, &in6addr_peer, &in6addr_my, 1234, 4242); TEST_IPV6_LONG_OK(ud, &in6addr_peer, &in6addr_my, 1234, 4242); TEST_IPV6_LONG_OK(ud, &in6addr_peer, &in6addr_my, 1234, 4242); TEST_IPV6_FAIL(ud, &in6addr_peer, &in6addr_my, 1234, 61400); TEST_IPV6_FAIL(ud, &in6addr_peer, &in6addr_my, 1234, 61400); UNREGISTER(ud); ud = REGISTER(AF_INET, &any_addr4, &any_addr4, 1234, 4242); TEST_IPV4_OK(ud, &in4addr_peer, &in4addr_my, 1234, 4242); TEST_IPV4_OK(ud, &in4addr_peer, &in4addr_my, 1234, 4242); TEST_IPV4_FAIL(ud, &in4addr_peer, &in4addr_my, 1234, 4325); TEST_IPV4_FAIL(ud, &in4addr_peer, &in4addr_my, 1234, 4325); UNREGISTER(ud); ud = REGISTER(AF_INET6, &any_addr6, NULL, 1234, 4242); TEST_IPV6_OK(ud, &in6addr_peer, &in6addr_my, 1234, 4242); TEST_IPV6_OK(ud, &in6addr_peer, &in6addr_my, 1234, 4242); TEST_IPV6_FAIL(ud, &in6addr_peer, &in6addr_my, 1234, 61400); TEST_IPV6_FAIL(ud, &in6addr_peer, &in6addr_my, 1234, 61400); UNREGISTER(ud); ud = REGISTER(AF_INET6, NULL, &any_addr6, 1234, 4242); TEST_IPV6_OK(ud, &in6addr_peer, &in6addr_my, 1234, 4242); TEST_IPV6_OK(ud, &in6addr_peer, &in6addr_my, 1234, 4242); TEST_IPV6_LONG_OK(ud, &in6addr_peer, &in6addr_my, 1234, 4242); TEST_IPV6_LONG_OK(ud, &in6addr_peer, &in6addr_my, 1234, 4242); TEST_IPV6_FAIL(ud, &in6addr_peer, &in6addr_my, 1234, 61400); TEST_IPV6_FAIL(ud, &in6addr_peer, &in6addr_my, 1234, 61400); UNREGISTER(ud); ud = REGISTER(AF_INET6, &peer_addr6, &my_addr6, 1234, 4242); TEST_IPV6_OK(ud, &in6addr_peer, &in6addr_my, 1234, 4242); TEST_IPV6_FAIL(ud, &in6addr_peer, &in6addr_my, 1234, 4243); ud = REGISTER(AF_INET, &peer_addr4, &my_addr4, 1234, 4242); TEST_IPV4_OK(ud, &in4addr_peer, &in4addr_my, 1234, 4242); TEST_IPV4_FAIL(ud, &in4addr_peer, &in4addr_my, 1234, 4243); ud = REGISTER(AF_UNSPEC, NULL, NULL, 1234, 42423); TEST_IPV4_OK(ud, &in4addr_peer, &in4addr_my, 1234, 42423); TEST_IPV6_OK(ud, &in6addr_peer, &in6addr_my, 1234, 42423); ud = REGISTER(AF_UNSPEC, NULL, NULL, 1234, 0); TEST_IPV4_OK(ud, &in4addr_peer, &in4addr_my, 1234, 42422); TEST_IPV6_OK(ud, &in6addr_peer, &in6addr_my, 1234, 42422); TEST_IPV4_OK(ud, &in4addr_peer, &in4addr_my, 1234, 42422); TEST_IPV6_OK(ud, &in6addr_peer, &in6addr_my, 1234, 42422); TEST_IPV4_FAIL(ud, &in4addr_peer, &in4addr_my, 12345, 42421); TEST_IPV6_FAIL(ud, &in6addr_peer, &in6addr_my, 12345, 42421); ud = REGISTER(AF_UNSPEC, NULL, NULL, 0, 0); TEST_IPV4_OK(ud, &in4addr_peer, &in4addr_my, 12345, 42421); TEST_IPV6_OK(ud, &in6addr_peer, &in6addr_my, 12345, 42421); TEST_IPV6_LONG_OK(ud, &in6addr_peer, &in6addr_my, 12345, 42421); /* Remote addr same as local addr, these two will never match */ REGISTER(AF_INET6, &my_addr6, NULL, 1234, 4242); REGISTER(AF_INET, &my_addr4, NULL, 1234, 4242); /* IPv4 remote addr and IPv6 remote addr, impossible combination */ REGISTER_FAIL(&my_addr4, &my_addr6, 1234, 4242); /**TESTPOINT: Check if tests passed*/ zassert_false(fail, "Tests failed"); i--; while (i) { ret = net_udp_unregister(handlers[i]); if (ret < 0 && ret != -ENOENT) { printk("Cannot unregister udp %d\n", i); zassert_true(0, "exiting"); } i--; } zassert_true((net_udp_unregister(NULL) < 0), "Unregister udp failed"); zassert_false(test_failed, "udp tests failed"); }