x3#!/usr/bin/env python # from switch_calc_headers import * from scapy.all import * from nf_sim_tools import * from collections import OrderedDict import sss_sdnet_tuples ######################## # pkt generation tools # ######################## pktsApplied = [] pktsExpected = [] # Pkt lists for SUME simulations nf_applied = OrderedDict() nf_applied[0] = [] nf_applied[1] = [] nf_applied[2] = [] nf_applied[3] = [] nf_expected = OrderedDict() nf_expected[0] = [] nf_expected[1] = [] nf_expected[2] = [] nf_expected[3] = [] nf_port_map = { "nf0":0b00000001, "nf1":0b00000100, "nf2":0b00010000, "nf3":0b01000000, "dma0":0b00000010 } nf_id_map = { "nf0":0, "nf1":1, "nf2":2, "nf3":3 } sss_sdnet_tuples.clear_tuple_files() def applyPkt(pkt, ingress, time): pktsApplied.append(pkt) sss_sdnet_tuples.sume_tuple_in['src_port'] = nf_port_map[ingress] sss_sdnet_tuples.sume_tuple_expect['src_port'] = nf_port_map[ingress] pkt.time = time nf_applied[nf_id_map[ingress]].append(pkt) def expPkt(pkt, egress): pktsExpected.append(pkt) sss_sdnet_tuples.sume_tuple_expect['dst_port'] = nf_port_map[egress] sss_sdnet_tuples.write_tuples() if egress in ["nf0","nf1","nf2","nf3"]: nf_expected[nf_id_map[egress]].append(pkt) elif egress == 'bcast': nf_expected[0].append(pkt) nf_expected[1].append(pkt) nf_expected[2].append(pkt) nf_expected[3].append(pkt) def print_summary(pkts): for pkt in pkts: print "summary = ", pkt.summary() def write_pcap_files(): wrpcap("src.pcap", pktsApplied) wrpcap("dst.pcap", pktsExpected) for i in nf_applied.keys(): if (len(nf_applied[i]) > 0): wrpcap('nf{0}_applied.pcap'.format(i), nf_applied[i]) for i in nf_expected.keys(): if (len(nf_expected[i]) > 0): wrpcap('nf{0}_expected.pcap'.format(i), nf_expected[i]) for i in nf_applied.keys(): print "nf{0}_applied times: ".format(i), [p.time for p in nf_applied[i]] ##################### # generate testdata # ##################### MAC1 = "08:11:11:11:11:08" MAC2 = "08:22:22:22:22:08" pktCnt = 0 INDEX_WIDTH = 4 REG_DEPTH = 2**INDEX_WIDTH # Not sure what this is used for NUM_KEYS = 4 lookup_table = { 0: 0x00000001, 1: 0x00000010, 2: 0x00000100, 3: 0x00001000 } # Test that packets are being mirrored def test_mirror(): pktCnt = 0 # First ethernet pktCnt += 1 pkt = Ether(dst=MAC2, src=MAC1) pkt = pad_pkt(pkt, 64) applyPkt(pkt, 'nf0', pktCnt) pktCnt += 1 pkt = Ether(dst=MAC1, src=MAC2) pkt = pad_pkt(pkt, 64) expPkt(pkt, 'nf0') # # Second IP # pktCnt += 1 # pkt = Ether(dst=MAC2, src=MAC1) / IPv6(src="fe80::1", dst="fe80::2") # pkt = pad_pkt(pkt, 64) # applyPkt(pkt, 'nf0', pktCnt) # pktCnt += 1 # pkt = Ether(dst=MAC1, src=MAC2) / IPv6(src="fe80::2", dst="fe80::1") # pkt = pad_pkt(pkt, 64) # expPkt(pkt, 'nf0') # # Third tcp # pktCnt += 1 # pkt = Ether(dst=MAC2, src=MAC1) / IPv6(src="fe80::1", dst="fe80::2") / TCP(sport=42, dport=23) # pkt = pad_pkt(pkt, 64) # applyPkt(pkt, 'nf0', pktCnt) # pktCnt += 1 # pkt = Ether(dst=MAC1, src=MAC2) / IPv6(src="fe80::2", dst="fe80::1") / TCP(sport=23, dport=42) # pkt = pad_pkt(pkt, 64) # expPkt(pkt, 'nf0') test_mirror() write_pcap_files()