aboutsummaryrefslogtreecommitdiffstats
path: root/test/test_ipsec_spd_flow_cache_input.py
diff options
context:
space:
mode:
authorZachary Leaf <zachary.leaf@arm.com>2021-06-25 08:11:15 -0500
committerFan Zhang <roy.fan.zhang@intel.com>2022-04-14 12:46:51 +0000
commit7cd35f5d688d9e3bddf66602655274dae944b086 (patch)
treea379d214f3036cecf5d13fe94f65dd4ba85c73f5 /test/test_ipsec_spd_flow_cache_input.py
parente1fd3903efe38880a45687299a414b1516994955 (diff)
ipsec: perf improvement of ipsec4_input_node using flow cache
Adding flow cache support to improve inbound IPv4/IPSec Security Policy Database (SPD) lookup performance. By enabling the flow cache in startup conf, this replaces a linear O(N) SPD search, with an O(1) hash table search. This patch is the ipsec4_input_node counterpart to https://gerrit.fd.io/r/c/vpp/+/31694, and shares much of the same code, theory and mechanism of action. Details about the flow cache: Mechanism: 1. First packet of a flow will undergo linear search in SPD table. Once a policy match is found, a new entry will be added into the flow cache. From 2nd packet onwards, the policy lookup will happen in flow cache. 2. The flow cache is implemented using a hash table without collision handling. This will avoid the logic to age out or recycle the old flows in flow cache. Whenever a collision occurs, the old entry will be overwritten by the new entry. Worst case is when all the 256 packets in a batch result in collision, falling back to linear search. Average and best case will be O(1). 3. The size of flow cache is fixed and decided based on the number of flows to be supported. The default is set to 1 million flows, but is configurable by a startup.conf option. 4. Whenever a SPD rule is added/deleted by the control plane, all current flow cache entries will be invalidated. As the SPD API is not mp-safe, the data plane will wait for the control plane operation to complete. Cache invalidation is via an epoch counter that is incremented on policy add/del and stored with each entry in the flow cache. If the epoch counter in the flow cache does not match the current count, the entry is considered stale, and we fall back to linear search. The following configurable options are available through startup conf under the ipsec{} entry: 1. ipv4-inbound-spd-flow-cache on/off - enable SPD flow cache (default off) 2. ipv4-inbound-spd-hash-buckets %d - set number of hash buckets (default 4,194,304: ~1 million flows with 25% load factor) Performance with 1 core, 1 ESP Tunnel, null-decrypt then bypass, 94B (null encrypted packet) for different SPD policy matching indices: SPD Policy index : 2 10 100 1000 Throughput : Mbps/Mbps Mbps/Mbps Mbps/Mbps Mbps/Mbps (Baseline/Optimized) ARM TX2 : 300/290 230/290 70/290 8.5/290 Type: improvement Signed-off-by: Zachary Leaf <zachary.leaf@arm.com> Signed-off-by: mgovind <govindarajan.Mohandoss@arm.com> Tested-by: Jieqiang Wang <jieqiang.wang@arm.com> Change-Id: I8be2ad4715accbb335c38cd933904119db75827b
Diffstat (limited to 'test/test_ipsec_spd_flow_cache_input.py')
-rw-r--r--test/test_ipsec_spd_flow_cache_input.py683
1 files changed, 683 insertions, 0 deletions
diff --git a/test/test_ipsec_spd_flow_cache_input.py b/test/test_ipsec_spd_flow_cache_input.py
new file mode 100644
index 00000000000..2d70d1540b8
--- /dev/null
+++ b/test/test_ipsec_spd_flow_cache_input.py
@@ -0,0 +1,683 @@
+from os import remove
+import socket
+import unittest
+
+from util import ppp
+from framework import VppTestRunner
+from template_ipsec import SpdFlowCacheTemplate
+
+
+class SpdFlowCacheInbound(SpdFlowCacheTemplate):
+ # Override setUpConstants to enable inbound flow cache in config
+ @classmethod
+ def setUpConstants(cls):
+ super(SpdFlowCacheInbound, cls).setUpConstants()
+ cls.vpp_cmdline.extend(["ipsec", "{",
+ "ipv4-inbound-spd-flow-cache on",
+ "}"])
+ cls.logger.info("VPP modified cmdline is %s" % " "
+ .join(cls.vpp_cmdline))
+
+
+class IPSec4SpdTestCaseBypass(SpdFlowCacheInbound):
+ """ IPSec/IPv4 inbound: Policy mode test case with flow cache \
+ (add bypass)"""
+ def test_ipsec_spd_inbound_bypass(self):
+ # In this test case, packets in IPv4 FWD path are configured
+ # to go through IPSec inbound SPD policy lookup.
+ #
+ # 2 inbound SPD rules (1 HIGH and 1 LOW) are added.
+ # - High priority rule action is set to DISCARD.
+ # - Low priority rule action is set to BYPASS.
+ #
+ # Since BYPASS rules take precedence over DISCARD
+ # (the order being PROTECT, BYPASS, DISCARD) we expect the
+ # BYPASS rule to match and traffic to be correctly forwarded.
+ self.create_interfaces(2)
+ pkt_count = 5
+
+ self.spd_create_and_intf_add(1, [self.pg1, self.pg0])
+
+ # create input rules
+ # bypass rule should take precedence over discard rule,
+ # even though it's lower priority
+ policy_0 = self.spd_add_rem_policy( # inbound, priority 10
+ 1, self.pg1, self.pg0, socket.IPPROTO_UDP,
+ is_out=0, priority=10, policy_type="bypass")
+ policy_1 = self.spd_add_rem_policy( # inbound, priority 15
+ 1, self.pg1, self.pg0, socket.IPPROTO_UDP,
+ is_out=0, priority=15, policy_type="discard")
+
+ # create output rule so we can capture forwarded packets
+ policy_2 = self.spd_add_rem_policy( # outbound, priority 10
+ 1, self.pg0, self.pg1, socket.IPPROTO_UDP,
+ is_out=1, priority=10, policy_type="bypass")
+
+ # check flow cache is empty before sending traffic
+ self.verify_num_inbound_flow_cache_entries(0)
+ # create the packet stream
+ packets = self.create_stream(self.pg0, self.pg1, pkt_count)
+ # add the stream to the source interface
+ self.pg0.add_stream(packets)
+ self.pg1.enable_capture()
+ self.pg_start()
+
+ # check capture on pg1
+ capture = self.pg1.get_capture()
+ for packet in capture:
+ try:
+ self.logger.debug(ppp("SPD Add - Got packet:", packet))
+ except Exception:
+ self.logger.error(ppp("Unexpected or invalid packet:", packet))
+ raise
+ self.logger.debug("SPD: Num packets: %s", len(capture.res))
+
+ # verify captured packets
+ self.verify_capture(self.pg0, self.pg1, capture)
+ # verify all policies matched the expected number of times
+ self.verify_policy_match(pkt_count, policy_0)
+ self.verify_policy_match(0, policy_1)
+ self.verify_policy_match(pkt_count, policy_2)
+ # check input policy has been cached
+ self.verify_num_inbound_flow_cache_entries(1)
+
+
+class IPSec4SpdTestCaseDiscard(SpdFlowCacheInbound):
+ """ IPSec/IPv4 inbound: Policy mode test case with flow cache \
+ (add discard)"""
+ def test_ipsec_spd_inbound_discard(self):
+ # In this test case, packets in IPv4 FWD path are configured
+ # to go through IPSec inbound SPD policy lookup.
+ # 1 DISCARD rule is added, so all traffic should be dropped.
+ self.create_interfaces(2)
+ pkt_count = 5
+
+ self.spd_create_and_intf_add(1, [self.pg1, self.pg0])
+
+ # create input rule
+ policy_0 = self.spd_add_rem_policy( # inbound, priority 10
+ 1, self.pg1, self.pg0, socket.IPPROTO_UDP,
+ is_out=0, priority=10, policy_type="discard")
+
+ # create output rule so we can capture forwarded packets
+ policy_1 = self.spd_add_rem_policy( # outbound, priority 10
+ 1, self.pg0, self.pg1, socket.IPPROTO_UDP,
+ is_out=1, priority=10, policy_type="bypass")
+
+ # check flow cache is empty before sending traffic
+ self.verify_num_inbound_flow_cache_entries(0)
+ # create the packet stream
+ packets = self.create_stream(self.pg0, self.pg1, pkt_count)
+ # add the stream to the source interface
+ self.pg0.add_stream(packets)
+ self.pg1.enable_capture()
+ self.pg_start()
+ # inbound discard rule should have dropped traffic
+ self.pg1.assert_nothing_captured()
+ # verify all policies matched the expected number of times
+ self.verify_policy_match(pkt_count, policy_0)
+ self.verify_policy_match(0, policy_1)
+ # only inbound discard rule should have been cached
+ self.verify_num_inbound_flow_cache_entries(1)
+
+
+class IPSec4SpdTestCaseRemove(SpdFlowCacheInbound):
+ """ IPSec/IPv4 inbound: Policy mode test case with flow cache \
+ (remove bypass)"""
+ def test_ipsec_spd_inbound_remove(self):
+ # In this test case, packets in IPv4 FWD path are configured
+ # to go through IPSec inbound SPD policy lookup.
+ #
+ # 2 inbound SPD rules (1 HIGH and 1 LOW) are added.
+ # - High priority rule action is set to DISCARD.
+ # - Low priority rule action is set to BYPASS.
+ #
+ # Since BYPASS rules take precedence over DISCARD
+ # (the order being PROTECT, BYPASS, DISCARD) we expect the
+ # BYPASS rule to match and traffic to be correctly forwarded.
+ #
+ # The BYPASS rules is then removed, and we check that all traffic
+ # is now correctly dropped.
+ self.create_interfaces(2)
+ pkt_count = 5
+
+ self.spd_create_and_intf_add(1, [self.pg1, self.pg0])
+
+ # create input rules
+ # bypass rule should take precedence over discard rule,
+ # even though it's lower priority
+ policy_0 = self.spd_add_rem_policy( # inbound, priority 10
+ 1, self.pg1, self.pg0, socket.IPPROTO_UDP,
+ is_out=0, priority=10, policy_type="bypass")
+ policy_1 = self.spd_add_rem_policy( # inbound, priority 15
+ 1, self.pg1, self.pg0, socket.IPPROTO_UDP,
+ is_out=0, priority=15, policy_type="discard")
+
+ # create output rule so we can capture forwarded packets
+ policy_2 = self.spd_add_rem_policy( # outbound, priority 10
+ 1, self.pg0, self.pg1, socket.IPPROTO_UDP,
+ is_out=1, priority=10, policy_type="bypass")
+
+ # check flow cache is empty before sending traffic
+ self.verify_num_inbound_flow_cache_entries(0)
+ # create the packet stream
+ packets = self.create_stream(self.pg0, self.pg1, pkt_count)
+ # add the stream to the source interface
+ self.pg0.add_stream(packets)
+ self.pg1.enable_capture()
+ self.pg_start()
+
+ # check capture on pg1
+ capture = self.pg1.get_capture()
+ for packet in capture:
+ try:
+ self.logger.debug(ppp("SPD Add - Got packet:", packet))
+ except Exception:
+ self.logger.error(ppp("Unexpected or invalid packet:", packet))
+ raise
+ self.logger.debug("SPD: Num packets: %s", len(capture.res))
+
+ # verify captured packets
+ self.verify_capture(self.pg0, self.pg1, capture)
+ # verify all policies matched the expected number of times
+ self.verify_policy_match(pkt_count, policy_0)
+ self.verify_policy_match(0, policy_1)
+ self.verify_policy_match(pkt_count, policy_2)
+ # check input policy has been cached
+ self.verify_num_inbound_flow_cache_entries(1)
+
+ # remove the input bypass rule
+ self.spd_add_rem_policy( # inbound, priority 10
+ 1, self.pg1, self.pg0, socket.IPPROTO_UDP,
+ is_out=0, priority=10, policy_type="bypass",
+ remove=True)
+ # verify flow cache counter has been reset by rule removal
+ self.verify_num_inbound_flow_cache_entries(0)
+
+ # resend the same packets
+ self.pg0.add_stream(packets)
+ self.pg1.enable_capture() # flush the old capture
+ self.pg_start()
+
+ # inbound discard rule should have dropped traffic
+ self.pg1.assert_nothing_captured()
+ # verify all policies matched the expected number of times
+ self.verify_policy_match(pkt_count, policy_0)
+ self.verify_policy_match(pkt_count, policy_1)
+ self.verify_policy_match(pkt_count, policy_2)
+ # by removing the bypass rule, we should have reset the flow cache
+ # we only expect the discard rule to now be in the flow cache
+ self.verify_num_inbound_flow_cache_entries(1)
+
+
+class IPSec4SpdTestCaseReadd(SpdFlowCacheInbound):
+ """ IPSec/IPv4 inbound: Policy mode test case with flow cache \
+ (add, remove, re-add bypass)"""
+ def test_ipsec_spd_inbound_readd(self):
+ # In this test case, packets in IPv4 FWD path are configured
+ # to go through IPSec inbound SPD policy lookup.
+ #
+ # 2 inbound SPD rules (1 HIGH and 1 LOW) are added.
+ # - High priority rule action is set to DISCARD.
+ # - Low priority rule action is set to BYPASS.
+ #
+ # Since BYPASS rules take precedence over DISCARD
+ # (the order being PROTECT, BYPASS, DISCARD) we expect the
+ # BYPASS rule to match and traffic to be correctly forwarded.
+ #
+ # The BYPASS rules is then removed, and we check that all traffic
+ # is now correctly dropped.
+ #
+ # The BYPASS rule is then readded, checking traffic is not forwarded
+ # correctly again
+ self.create_interfaces(2)
+ pkt_count = 5
+
+ self.spd_create_and_intf_add(1, [self.pg1, self.pg0])
+
+ # create input rules
+ # bypass rule should take precedence over discard rule,
+ # even though it's lower priority
+ policy_0 = self.spd_add_rem_policy( # inbound, priority 10
+ 1, self.pg1, self.pg0, socket.IPPROTO_UDP,
+ is_out=0, priority=10, policy_type="bypass")
+ policy_1 = self.spd_add_rem_policy( # inbound, priority 15
+ 1, self.pg1, self.pg0, socket.IPPROTO_UDP,
+ is_out=0, priority=15, policy_type="discard")
+
+ # create output rule so we can capture forwarded packets
+ policy_2 = self.spd_add_rem_policy( # outbound, priority 10
+ 1, self.pg0, self.pg1, socket.IPPROTO_UDP,
+ is_out=1, priority=10, policy_type="bypass")
+
+ # check flow cache is empty before sending traffic
+ self.verify_num_inbound_flow_cache_entries(0)
+ # create the packet stream
+ packets = self.create_stream(self.pg0, self.pg1, pkt_count)
+ # add the stream to the source interface
+ self.pg0.add_stream(packets)
+ self.pg1.enable_capture()
+ self.pg_start()
+
+ # check capture on pg1
+ capture = self.pg1.get_capture()
+ for packet in capture:
+ try:
+ self.logger.debug(ppp("SPD Add - Got packet:", packet))
+ except Exception:
+ self.logger.error(ppp("Unexpected or invalid packet:", packet))
+ raise
+ self.logger.debug("SPD: Num packets: %s", len(capture.res))
+
+ # verify captured packets
+ self.verify_capture(self.pg0, self.pg1, capture)
+ # verify all policies matched the expected number of times
+ self.verify_policy_match(pkt_count, policy_0)
+ self.verify_policy_match(0, policy_1)
+ self.verify_policy_match(pkt_count, policy_2)
+ # check input policy has been cached
+ self.verify_num_inbound_flow_cache_entries(1)
+
+ # remove the input bypass rule
+ self.spd_add_rem_policy( # inbound, priority 10
+ 1, self.pg1, self.pg0, socket.IPPROTO_UDP,
+ is_out=0, priority=10, policy_type="bypass",
+ remove=True)
+ # verify flow cache counter has been reset by rule removal
+ self.verify_num_inbound_flow_cache_entries(0)
+
+ # resend the same packets
+ self.pg0.add_stream(packets)
+ self.pg1.enable_capture() # flush the old capture
+ self.pg_start()
+
+ # inbound discard rule should have dropped traffic
+ self.pg1.assert_nothing_captured()
+ # verify all policies matched the expected number of times
+ self.verify_policy_match(pkt_count, policy_0)
+ self.verify_policy_match(pkt_count, policy_1)
+ self.verify_policy_match(pkt_count, policy_2)
+ # by removing the bypass rule, flow cache was reset
+ # we only expect the discard rule to now be in the flow cache
+ self.verify_num_inbound_flow_cache_entries(1)
+
+ # readd the input bypass rule
+ policy_0 = self.spd_add_rem_policy( # inbound, priority 10
+ 1, self.pg1, self.pg0, socket.IPPROTO_UDP,
+ is_out=0, priority=10, policy_type="bypass")
+ # verify flow cache counter has been reset by rule addition
+ self.verify_num_inbound_flow_cache_entries(0)
+
+ # resend the same packets
+ self.pg0.add_stream(packets)
+ self.pg1.enable_capture() # flush the old capture
+ self.pg_start()
+
+ # check capture on pg1
+ capture = self.pg1.get_capture()
+ for packet in capture:
+ try:
+ self.logger.debug(ppp("SPD Add - Got packet:", packet))
+ except Exception:
+ self.logger.error(ppp("Unexpected or invalid packet:", packet))
+ raise
+
+ # verify captured packets
+ self.verify_capture(self.pg0, self.pg1, capture)
+ # verify all policies matched the expected number of times
+ self.verify_policy_match(pkt_count, policy_0)
+ self.verify_policy_match(pkt_count, policy_1)
+ self.verify_policy_match(pkt_count*2, policy_2)
+ # by readding the bypass rule, we reset the flow cache
+ # we only expect the bypass rule to now be in the flow cache
+ self.verify_num_inbound_flow_cache_entries(1)
+
+
+class IPSec4SpdTestCaseMultiple(SpdFlowCacheInbound):
+ """ IPSec/IPv4 inbound: Policy mode test case with flow cache \
+ (multiple interfaces, multiple rules)"""
+ def test_ipsec_spd_inbound_multiple(self):
+ # In this test case, packets in IPv4 FWD path are configured to go
+ # through IPSec outbound SPD policy lookup.
+ #
+ # Multiples rules on multiple interfaces are tested at the same time.
+ # 3x interfaces are configured, binding the same SPD to each.
+ # Each interface has 1 SPD rule- 2x BYPASS and 1x DISCARD
+ #
+ # Traffic should be forwarded with destinations pg1 & pg2
+ # and dropped to pg0.
+ self.create_interfaces(3)
+ pkt_count = 5
+ # bind SPD to all interfaces
+ self.spd_create_and_intf_add(1, self.pg_interfaces)
+ # add input rules on all interfaces
+ # pg0 -> pg1
+ policy_0 = self.spd_add_rem_policy( # inbound, priority 10
+ 1, self.pg1, self.pg0, socket.IPPROTO_UDP,
+ is_out=0, priority=10, policy_type="bypass")
+ # pg1 -> pg2
+ policy_1 = self.spd_add_rem_policy( # inbound, priority 10
+ 1, self.pg2, self.pg1, socket.IPPROTO_UDP,
+ is_out=0, priority=10, policy_type="bypass")
+ # pg2 -> pg0
+ policy_2 = self.spd_add_rem_policy( # inbound, priority 10
+ 1, self.pg0, self.pg2, socket.IPPROTO_UDP,
+ is_out=0, priority=10, policy_type="discard")
+
+ # create output rules covering the the full ip range
+ # 0.0.0.0 -> 255.255.255.255, so we can capture forwarded packets
+ policy_3 = self.spd_add_rem_policy( # outbound, priority 10
+ 1, self.pg0, self.pg0, socket.IPPROTO_UDP,
+ is_out=1, priority=10, policy_type="bypass",
+ all_ips=True)
+
+ # check flow cache is empty (0 active elements) before sending traffic
+ self.verify_num_inbound_flow_cache_entries(0)
+
+ # create the packet streams
+ packets0 = self.create_stream(self.pg0, self.pg1, pkt_count)
+ packets1 = self.create_stream(self.pg1, self.pg2, pkt_count)
+ packets2 = self.create_stream(self.pg2, self.pg0, pkt_count)
+ # add the streams to the source interfaces
+ self.pg0.add_stream(packets0)
+ self.pg1.add_stream(packets1)
+ self.pg2.add_stream(packets2)
+ # enable capture on all interfaces
+ for pg in self.pg_interfaces:
+ pg.enable_capture()
+ # start the packet generator
+ self.pg_start()
+
+ # get captures from ifs
+ if_caps = []
+ for pg in [self.pg1, self.pg2]: # we are expecting captures on pg1/pg2
+ if_caps.append(pg.get_capture())
+ for packet in if_caps[-1]:
+ try:
+ self.logger.debug(ppp("SPD Add - Got packet:", packet))
+ except Exception:
+ self.logger.error(
+ ppp("Unexpected or invalid packet:", packet))
+ raise
+
+ # verify captures that matched BYPASS rules
+ self.verify_capture(self.pg0, self.pg1, if_caps[0])
+ self.verify_capture(self.pg1, self.pg2, if_caps[1])
+ # verify that traffic to pg0 matched DISCARD rule and was dropped
+ self.pg0.assert_nothing_captured()
+ # verify all policies matched the expected number of times
+ self.verify_policy_match(pkt_count, policy_0)
+ self.verify_policy_match(pkt_count, policy_1)
+ self.verify_policy_match(pkt_count, policy_2)
+ # check flow/policy match was cached for: 3x input policies
+ self.verify_num_inbound_flow_cache_entries(3)
+
+
+class IPSec4SpdTestCaseOverwriteStale(SpdFlowCacheInbound):
+ """ IPSec/IPv4 inbound: Policy mode test case with flow cache \
+ (overwrite stale entries)"""
+ def test_ipsec_spd_inbound_overwrite(self):
+ # The operation of the flow cache is setup so that the entire cache
+ # is invalidated when adding or removing an SPD policy rule.
+ # For performance, old cache entries are not zero'd, but remain
+ # in the table as "stale" entries. If a flow matches a stale entry,
+ # and the epoch count does NOT match the current count, the entry
+ # is overwritten.
+ # In this test, 3 active rules are created and matched to enter
+ # them into the flow cache.
+ # A single entry is removed to invalidate the entire cache.
+ # We then readd the rule and test that overwriting of the previous
+ # stale entries occurs as expected, and that the flow cache entry
+ # counter is updated correctly.
+ self.create_interfaces(3)
+ pkt_count = 5
+ # bind SPD to all interfaces
+ self.spd_create_and_intf_add(1, self.pg_interfaces)
+ # add input rules on all interfaces
+ # pg0 -> pg1
+ policy_0 = self.spd_add_rem_policy( # inbound
+ 1, self.pg1, self.pg0, socket.IPPROTO_UDP,
+ is_out=0, priority=10, policy_type="bypass")
+ # pg1 -> pg2
+ policy_1 = self.spd_add_rem_policy( # inbound
+ 1, self.pg2, self.pg1, socket.IPPROTO_UDP,
+ is_out=0, priority=10, policy_type="bypass")
+ # pg2 -> pg0
+ policy_2 = self.spd_add_rem_policy( # inbound
+ 1, self.pg0, self.pg2, socket.IPPROTO_UDP,
+ is_out=0, priority=10, policy_type="discard")
+
+ # create output rules covering the the full ip range
+ # 0.0.0.0 -> 255.255.255.255, so we can capture forwarded packets
+ policy_3 = self.spd_add_rem_policy( # outbound
+ 1, self.pg0, self.pg0, socket.IPPROTO_UDP,
+ is_out=1, priority=10, policy_type="bypass",
+ all_ips=True)
+
+ # check flow cache is empty (0 active elements) before sending traffic
+ self.verify_num_inbound_flow_cache_entries(0)
+
+ # create the packet streams
+ packets0 = self.create_stream(self.pg0, self.pg1, pkt_count)
+ packets1 = self.create_stream(self.pg1, self.pg2, pkt_count)
+ packets2 = self.create_stream(self.pg2, self.pg0, pkt_count)
+ # add the streams to the source interfaces
+ self.pg0.add_stream(packets0)
+ self.pg1.add_stream(packets1)
+ self.pg2.add_stream(packets2)
+ # enable capture on all interfaces
+ for pg in self.pg_interfaces:
+ pg.enable_capture()
+ # start the packet generator
+ self.pg_start()
+
+ # get captures from ifs
+ if_caps = []
+ for pg in [self.pg1, self.pg2]: # we are expecting captures on pg1/pg2
+ if_caps.append(pg.get_capture())
+ for packet in if_caps[-1]:
+ try:
+ self.logger.debug(ppp("SPD Add - Got packet:", packet))
+ except Exception:
+ self.logger.error(
+ ppp("Unexpected or invalid packet:", packet))
+ raise
+
+ # verify captures that matched BYPASS rules
+ self.verify_capture(self.pg0, self.pg1, if_caps[0])
+ self.verify_capture(self.pg1, self.pg2, if_caps[1])
+ # verify that traffic to pg0 matched DISCARD rule and was dropped
+ self.pg0.assert_nothing_captured()
+ # verify all policies matched the expected number of times
+ self.verify_policy_match(pkt_count, policy_0)
+ self.verify_policy_match(pkt_count, policy_1)
+ self.verify_policy_match(pkt_count, policy_2)
+ # check flow/policy match was cached for: 3x input policies
+ self.verify_num_inbound_flow_cache_entries(3)
+
+ # adding an outbound policy should not invalidate output flow cache
+ self.spd_add_rem_policy( # outbound
+ 1, self.pg0, self.pg0, socket.IPPROTO_UDP,
+ is_out=1, priority=1, policy_type="bypass",
+ all_ips=True)
+ # check inbound flow cache counter has not been reset
+ self.verify_num_inbound_flow_cache_entries(3)
+
+ # remove + readd bypass policy - flow cache counter will be reset,
+ # and there will be 3x stale entries in flow cache
+ self.spd_add_rem_policy( # inbound, priority 10
+ 1, self.pg1, self.pg0, socket.IPPROTO_UDP,
+ is_out=0, priority=10, policy_type="bypass",
+ remove=True)
+ # readd policy
+ policy_0 = self.spd_add_rem_policy( # inbound, priority 10
+ 1, self.pg1, self.pg0, socket.IPPROTO_UDP,
+ is_out=0, priority=10, policy_type="bypass")
+ # check counter was reset
+ self.verify_num_inbound_flow_cache_entries(0)
+
+ # resend the same packets
+ self.pg0.add_stream(packets0)
+ self.pg1.add_stream(packets1)
+ self.pg2.add_stream(packets2)
+ for pg in self.pg_interfaces:
+ pg.enable_capture() # flush previous captures
+ self.pg_start()
+
+ # get captures from ifs
+ if_caps = []
+ for pg in [self.pg1, self.pg2]: # we are expecting captures on pg1/pg2
+ if_caps.append(pg.get_capture())
+ for packet in if_caps[-1]:
+ try:
+ self.logger.debug(ppp("SPD Add - Got packet:", packet))
+ except Exception:
+ self.logger.error(
+ ppp("Unexpected or invalid packet:", packet))
+ raise
+
+ # verify captures that matched BYPASS rules
+ self.verify_capture(self.pg0, self.pg1, if_caps[0])
+ self.verify_capture(self.pg1, self.pg2, if_caps[1])
+ # verify that traffic to pg0 matched DISCARD rule and was dropped
+ self.pg0.assert_nothing_captured()
+ # verify all policies matched the expected number of times
+ self.verify_policy_match(pkt_count, policy_0)
+ self.verify_policy_match(pkt_count*2, policy_1)
+ self.verify_policy_match(pkt_count*2, policy_2)
+ # we are overwriting 3x stale entries - check flow cache counter
+ # is correct
+ self.verify_num_inbound_flow_cache_entries(3)
+
+
+class IPSec4SpdTestCaseCollision(SpdFlowCacheInbound):
+ """ IPSec/IPv4 inbound: Policy mode test case with flow cache \
+ (hash collision)"""
+ # Override class setup to restrict hash table size to 16 buckets.
+ # This forces using only the lower 4 bits of the hash as a key,
+ # making hash collisions easy to find.
+ @classmethod
+ def setUpConstants(cls):
+ super(SpdFlowCacheInbound, cls).setUpConstants()
+ cls.vpp_cmdline.extend(["ipsec", "{",
+ "ipv4-inbound-spd-flow-cache on",
+ "ipv4-inbound-spd-hash-buckets 16",
+ "}"])
+ cls.logger.info("VPP modified cmdline is %s" % " "
+ .join(cls.vpp_cmdline))
+
+ def test_ipsec_spd_inbound_collision(self):
+ # The flow cache operation is setup to overwrite an entry
+ # if a hash collision occurs.
+ # In this test, 2 packets are configured that result in a
+ # hash with the same lower 4 bits.
+ # After the first packet is received, there should be one
+ # active entry in the flow cache.
+ # After the second packet with the same lower 4 bit hash
+ # is received, this should overwrite the same entry.
+ # Therefore there will still be a total of one (1) entry,
+ # in the flow cache with two matching policies.
+ # crc32_supported() method is used to check cpu for crc32
+ # intrinsic support for hashing.
+ # If crc32 is not supported, we fall back to clib_xxhash()
+ self.create_interfaces(4)
+ pkt_count = 5
+ # bind SPD to all interfaces
+ self.spd_create_and_intf_add(1, self.pg_interfaces)
+
+ # create output rules covering the the full ip range
+ # 0.0.0.0 -> 255.255.255.255, so we can capture forwarded packets
+ policy_0 = self.spd_add_rem_policy( # outbound
+ 1, self.pg0, self.pg0, socket.IPPROTO_UDP,
+ is_out=1, priority=10, policy_type="bypass",
+ all_ips=True)
+
+ capture_intfs = []
+ if self.crc32_supported(): # create crc32 collision on last 4 bits
+ hashed_with_crc32 = True
+ # add matching rules
+ policy_1 = self.spd_add_rem_policy( # inbound, priority 10
+ 1, self.pg1, self.pg2, socket.IPPROTO_UDP,
+ is_out=0, priority=10, policy_type="bypass")
+ policy_2 = self.spd_add_rem_policy( # inbound, priority 10
+ 1, self.pg3, self.pg0, socket.IPPROTO_UDP,
+ is_out=0, priority=10, policy_type="bypass")
+
+ # we expect to get captures on pg1 + pg3
+ capture_intfs.append(self.pg1)
+ capture_intfs.append(self.pg3)
+
+ # check flow cache is empty before sending traffic
+ self.verify_num_inbound_flow_cache_entries(0)
+
+ # create the packet streams
+ # packet hashes to:
+ # ad727628
+ packets1 = self.create_stream(self.pg2, self.pg1, pkt_count, 1, 1)
+ # b5512898
+ packets2 = self.create_stream(self.pg0, self.pg3, pkt_count, 1, 1)
+ # add the streams to the source interfaces
+ self.pg2.add_stream(packets1)
+ self.pg0.add_stream(packets2)
+ else: # create xxhash collision on last 4 bits
+ hashed_with_crc32 = False
+ # add matching rules
+ policy_1 = self.spd_add_rem_policy( # inbound, priority 10
+ 1, self.pg1, self.pg2, socket.IPPROTO_UDP,
+ is_out=0, priority=10, policy_type="bypass")
+ policy_2 = self.spd_add_rem_policy( # inbound, priority 10
+ 1, self.pg2, self.pg3, socket.IPPROTO_UDP,
+ is_out=0, priority=10, policy_type="bypass")
+
+ capture_intfs.append(self.pg1)
+ capture_intfs.append(self.pg2)
+
+ # check flow cache is empty before sending traffic
+ self.verify_num_inbound_flow_cache_entries(0)
+
+ # create the packet streams
+ # 2f8f90f557eef12c
+ packets1 = self.create_stream(self.pg2, self.pg1, pkt_count, 1, 1)
+ # 6b7f9987719ffc1c
+ packets2 = self.create_stream(self.pg3, self.pg2, pkt_count, 1, 1)
+ # add the streams to the source interfaces
+ self.pg2.add_stream(packets1)
+ self.pg3.add_stream(packets2)
+
+ # enable capture on interfaces we expect capture on & send pkts
+ for pg in capture_intfs:
+ pg.enable_capture()
+ self.pg_start()
+
+ # get captures
+ if_caps = []
+ for pg in capture_intfs:
+ if_caps.append(pg.get_capture())
+ for packet in if_caps[-1]:
+ try:
+ self.logger.debug(ppp(
+ "SPD Add - Got packet:", packet))
+ except Exception:
+ self.logger.error(ppp(
+ "Unexpected or invalid packet:", packet))
+ raise
+
+ # verify captures that matched BYPASS rule
+ if(hashed_with_crc32):
+ self.verify_capture(self.pg2, self.pg1, if_caps[0])
+ self.verify_capture(self.pg0, self.pg3, if_caps[1])
+ else: # hashed with xxhash
+ self.verify_capture(self.pg2, self.pg1, if_caps[0])
+ self.verify_capture(self.pg3, self.pg2, if_caps[1])
+
+ # verify all policies matched the expected number of times
+ self.verify_policy_match(pkt_count, policy_1)
+ self.verify_policy_match(pkt_count, policy_2)
+ self.verify_policy_match(pkt_count*2, policy_0) # output policy
+ # we have matched 2 policies, but due to the hash collision
+ # one active entry is expected
+ self.verify_num_inbound_flow_cache_entries(1)
+
+
+if __name__ == '__main__':
+ unittest.main(testRunner=VppTestRunner)