From patchwork Tue Aug 1 11:37:44 2023 Content-Type: text/plain; charset="utf-8" MIME-Version: 1.0 Content-Transfer-Encoding: 7bit X-Patchwork-Submitter: Jamal Hadi Salim X-Patchwork-Id: 13336570 Received: from lindbergh.monkeyblade.net (lindbergh.monkeyblade.net [23.128.96.19]) (using TLSv1.2 with cipher ECDHE-RSA-AES256-GCM-SHA384 (256/256 bits)) (No client certificate requested) by smtp.subspace.kernel.org (Postfix) with ESMTPS id A0E511F952 for ; Tue, 1 Aug 2023 11:47:42 +0000 (UTC) Received: from mail-qv1-xf36.google.com (mail-qv1-xf36.google.com [IPv6:2607:f8b0:4864:20::f36]) by lindbergh.monkeyblade.net (Postfix) with ESMTPS id 7F099D3 for ; Tue, 1 Aug 2023 04:38:19 -0700 (PDT) Received: by mail-qv1-xf36.google.com with SMTP id 6a1803df08f44-63cff46ddb8so30833986d6.1 for ; Tue, 01 Aug 2023 04:38:19 -0700 (PDT) DKIM-Signature: v=1; a=rsa-sha256; c=relaxed/relaxed; d=mojatatu-com.20221208.gappssmtp.com; s=20221208; t=1690889898; x=1691494698; h=content-transfer-encoding:mime-version:message-id:date:subject:cc :to:from:from:to:cc:subject:date:message-id:reply-to; bh=Nf6syk96kT3aKHfXOIM4hdNEDRE+wmFCbvRMOBWb3D0=; b=ggTVQjSALoluK1a22ypVfxp53KN4jTOq503LBMVJ/WFG4ivxIQbjrxCv373FnQMXzJ swZ7Cp/6037p+yZqu4ONNT7i70cgHTycMPWtYcwXn7GNXbbs4ABeokdo5hsDRvf94AnX P1jrTJVi5ktHgfMYnvaR58HJrdqLYPMnNx7ijjiCGTB+EDCDFYT42D3fWxmIUSR6fJmH mvgatKyYTVbYTDoa8zxprldLy7xTbAlLp4WCSewyoLEmKQzFW81iiE/jqJOcEGjTn8sH 8sQ8t0+kEJfR8ZUx/1r9HZjblb4rODtU2RSZc52saPrOxIavlCskdax8h6sGZKGjFLCe UjpA== X-Google-DKIM-Signature: v=1; a=rsa-sha256; c=relaxed/relaxed; d=1e100.net; s=20221208; t=1690889898; x=1691494698; h=content-transfer-encoding:mime-version:message-id:date:subject:cc :to:from:x-gm-message-state:from:to:cc:subject:date:message-id :reply-to; bh=Nf6syk96kT3aKHfXOIM4hdNEDRE+wmFCbvRMOBWb3D0=; b=K+KwIVXJB3kbI/5h1aIio13CjIRZmWsD3QK673MPnUrBDMAjO/gUYv0eExf1JD36AA sdpu0+6w1L9KDX/1o1aGt94txomEZjWAXW0cXnFROlAvFe8o9MYLzW+2mey6k9XqpR3R O+JBKM5EVIydsXhDcSQL8hrwyYeQRxOoaAne/+anPlLjHg623HC6vwfKQk2ofBP9ghWi zcUCCabX+rpFeKUnA5RbeHbS8nUtJPmE/WTUUYRCm0wVv75UYkGbldp1hjBJ/1ELqs0O jVTofQ1knCyNYy3AJQL556Gyp6Ay7fyyh/mlPCBSTmh3t6OiBknc7oCHEUZ/K29avvnm d4Ng== X-Gm-Message-State: ABy/qLZXW/DOz5Fj97HZlVH6Hq/As32sFcjtL2Y0SJabcGexIkaR/tHh XuAPx03T/X6og/KJ7zyZcSc8lBFXlFFOLMu6ItHNiw== X-Google-Smtp-Source: APBJJlF9McP760R6s98yPY8PFkGtRI4mHLOcsWMLK4Z2qeQtV41srZnlSvnMin2l5p3R6sCZj0PJzw== X-Received: by 2002:a05:6214:2b05:b0:635:da80:e53a with SMTP id jx5-20020a0562142b0500b00635da80e53amr17558859qvb.12.1690889897828; Tue, 01 Aug 2023 04:38:17 -0700 (PDT) Received: from majuu.waya ([142.114.148.137]) by smtp.gmail.com with ESMTPSA id j1-20020a0cf501000000b0063d26033b74sm4643738qvm.39.2023.08.01.04.38.16 (version=TLS1_3 cipher=TLS_AES_256_GCM_SHA384 bits=256/256); Tue, 01 Aug 2023 04:38:16 -0700 (PDT) From: Jamal Hadi Salim To: netdev@vger.kernel.org Cc: deb.chatterjee@intel.com, anjali.singhai@intel.com, namrata.limaye@intel.com, tom@sipanda.io, mleitner@redhat.com, Mahesh.Shirshyad@amd.com, Vipin.Jain@amd.com, tomasz.osinski@intel.com, jiri@resnulli.us, xiyou.wangcong@gmail.com, davem@davemloft.net, edumazet@google.com, kuba@kernel.org, pabeni@redhat.com, vladbu@nvidia.com, simon.horman@corigine.com, khalidm@nvidia.com, toke@redhat.com, mattyk@nvidia.com, john.andy.fingerhut@intel.com, dan.daly@intel.com Subject: [PATCH RFC v5 net-next 00/23] Introducing P4TC Date: Tue, 1 Aug 2023 07:37:44 -0400 Message-Id: <20230801113807.85473-1-jhs@mojatatu.com> X-Mailer: git-send-email 2.34.1 Precedence: bulk X-Mailing-List: netdev@vger.kernel.org List-Id: List-Subscribe: List-Unsubscribe: MIME-Version: 1.0 X-Spam-Status: No, score=-1.9 required=5.0 tests=BAYES_00,DKIM_SIGNED, DKIM_VALID,RCVD_IN_DNSWL_NONE,SPF_HELO_NONE,SPF_NONE, T_SCC_BODY_TEXT_LINE,URIBL_BLOCKED autolearn=ham autolearn_force=no version=3.4.6 X-Spam-Checker-Version: SpamAssassin 3.4.6 (2021-04-09) on lindbergh.monkeyblade.net X-Patchwork-Delegate: kuba@kernel.org X-Patchwork-State: RFC We are seeking community feedback on P4TC patches. Please do note that ~50% of LOC are testcases. Changes In RFC Version 2 ------------------------- Version 2 is the initial integration of the eBPF datapath. We took into consideration suggestions provided to use eBPF and put effort into analyzing eBPF as datapath which involved extensive testing. We implemented 6 approaches with eBPF and ran performance analysis and presented our results at the P4 2023 workshop in Santa Clara[see: 1, 3] on each of the 6 vs the scriptable P4TC and concluded that 2 of the approaches are sensible (4 if you account for XDP or TC separately). Conclusions from the exercise: We lose the simple operational model we had prior to integrating eBPF. We do gain performance in most cases when the datapath is less compute-bound. For more discussion on our requirements vs journeying the eBPF path please scroll down to "Restating Our Requirements" and "Challenges". This patch set presented two modes. mode1: the parser is entirely based on eBPF - whereas the rest of the SW datapath stays as _scriptable_ as in Version 1. mode2: All of the kernel s/w datapath (including parser) is in eBPF. The key ingredient for eBPF, that we did not have access to in the past, is kfunc (it made a big difference for us to reconsider eBPF). In V2 the two modes are mutually exclusive (IOW, you get to choose one or the other via Kconfig). Changes In RFC Version 3 ------------------------- These patches are still in a little bit of flux as we adjust to integrating eBPF. So there are small constructs that are used in V1 and 2 but no longer used in this version. We will make a V4 which will remove those. The changes from V2 are as follows: 1) Feedback we got in V2 is to try stick to one of the two modes. In this version we are taking one more step and going the path of mode2 vs v2 where we had 2 modes. 2) The P4 Register extern is no longer standalone. Instead, as part of integrating into eBPF we introduce another kfunc which encapsulates Register as part of the extern interface. 3) We have improved our CICD to include tools pointed to us by Simon. See "Testing" further below. Thanks to Simon for that and other issues he caught. Simon, we discussed on issue [7] but decided to keep that log since we think it is useful. 4) A lot of small cleanups. Thanks Marcelo. There are two things we need to re-discuss though; see: [5], [6]. 5) We removed the need for a range of IDs for dynamic actions. Thanks Jakub. 6) Clarify ambiguity caused by smatch in an if(A) else if(B) condition. We are guaranteed that either A or B must exist; however, lets make smatch happy. Thanks to Simon and Dan Carpenter. Changes In RFC Version 4 ------------------------- 1) More integration from scriptable to eBPF. Small bug fixes. 2) More streamlining support of externs via kfunc (one additional kfunc). 3) Removed per-cpu scratchpad per Toke's suggestion and instead use XDP metadata. There is more eBPF integration coming. One thing we looked at but is not in this patchset but should be in the next is use of eBPF link in our loading (see "challenge #1" further below). Changes In RFC Version 5 ------------------------- 1) More integration from scriptable view to eBPF. Small bug fixes from last integration. 2) More streamlining support of externs via kfunc (create-on-miss, etc) 3) eBPF linking for XDP. There is more eBPF integration/streamlining coming (we are getting close to conversion from scriptable domain). What is P4? ----------- The Programming Protocol-independent Packet Processors (P4) is an open source, domain-specific programming language for specifying data plane behavior. The P4 ecosystem includes an extensive range of deployments, products, projects and services, etc. For Details, visit: https://p4.org/ __What is P4TC?__ P4TC is an implementation of P4 building on top of many years of Linux TC experiences. On why P4 - see small treatise here:[4]. There have been many discussions and meetings since about 2015 in regards to P4 over TC [2] and we are finally proving the naysayers that we do get stuff done! A lot more of the P4TC motivation is captured at: https://github.com/p4tc-dev/docs/blob/main/why-p4tc.md XXX: To be updated to describe integration with eBPF as datapath. **In this patch series we focus on s/w datapath only**. __P4TC Workflow__ These patches enable kernel and user space code change _independency_ for any new P4 program that describes a new datapath. The workflow is as follows: 1) A developer writes a P4 program, "myprog" 2) Compiles it using the P4C compiler[8]. The compiler generates 3 outputs: a) shell script(s) which form template definitions for the different P4 objects "myprog" utilizes (tables, externs, actions etc). b) the parser and the rest of the datapath are generated in eBPF and need to be compiled into binaries. c) A json introspection file used for control plane (by iproute2/tc). 3) The developer (or operator) executes the shell script(s) to manifest the functional s/w equivalent of "myprog" into the kernel. 4) The developer (or operator) instantiates "myprog" via the tc P4 filter to ingress/egress (depending on P4 arch) of one or more netdevs/ports. Example1: parser is an action: "tc filter add block 22 ingress protocol all prio 1 p4 pname myprog \ action bpf obj $PARSER.o section parser/tc-ingress \ action bpf obj $PROGNAME.o section p4prog/tc" Example2: parser explicitly bound and rest of dpath as an action: "tc filter add block 22 ingress protocol all prio 1 p4 pname myprog \ prog tc obj $PARSER.o section parser/tc-ingress \ action bpf obj $PROGNAME.o section p4prog/tc" Example3: parser is at XDP, rest of dpath as an action: "tc filter add block 22 ingress protocol all prio 1 p4 pname myprog \ prog type xdp obj $PARSER.o section parser/xdp-ingress xdp_cookie 123 \ pinned_link /path/to/xdp-prog-link \ action bpf obj $PROGNAME.o section p4prog/tc" Example4: parser+prog at XDP: "tc filter add block 22 ingress protocol all prio 1 p4 pname myprog \ prog type xdp obj $PROGNAME.o section p4prog/xdp xdp_cookie 123 \ pinned_link /path/to/xdp-prog-link" see individual patches for more examples tc vs xdp etc. Also see section on "challenges". Once "myprog" P4 program is instantiated one can start updating table entries that are associated with myprog's table named "mytable". Example: tc p4runtime create myprog/table/mytable dstAddr 10.0.1.2/32 \ action send_to_port param port eno1 A packet arriving on ingress of any of the ports on block 22 will first be exercised via the (eBPF) parser to find the headers pointing to the ip destination address. The remainder eBPF datapath uses the result dstAddr as a key to (kfunc) lookup myprog's mytable which returns the action params which are then used to execute the action in the eBPF datapath (eventually sending out packets to eno1). On a miss, mytable's default miss action is executed. __Description of Patches__ P4TC is designed to have no impact on the core code for other users of TC. IOW, you can compile it out or as a module and if you dont use it then there should be no impact on your performance. We do make core kernel changes. Patch #1 adds infrastructure for "dynamic" actions that can be created on "the fly" based on the P4 program requirement. This patch makes a small incision into act_api which shouldn't affect the performance (or functionality) of the existing actions. Patches 2-5,7 are minimalist enablers for P4TC and have no effect the classical tc action. Patch 6 adds infrastructure support for preallocation of dynamic actions. The core P4TC code implements several P4 objects. 1) Patch #9 introduces P4 data types which are consumed by the rest of the code 2) Patch #10 introduces the concept of templating Pipelines. i.e CRUD commands for P4 pipelines. 3) Patch #11 introduces the concept of P4 header fields and associated CRUD template commands. 4) Patch #12 introduces the concept of action templates and associated CRUD commands. 5) Patch #13 introduces the concept of P4 table templates and associated CRUD commands for tables 6) Patch #14 introduces table entries and associated CRUD commands. 7) Patch #15 introduces interaction of eBPF to P4TC domain via kfunc. 8) Patch #16 introduces the TC classifier P4 used at runtime. 9) Patch #17 introduces extern interfacing (both template and runtime). 10) Patches #18-22 are control tests for the different objects (we left out some for brevity). __Testing__ Speaking of testing - we have ~300 tdc test cases. This number is growing and we are adjusting to accommodate for eBPF. These tests are run on our CICD system on pull requests and after commits are approved. The CICD does a lot of other tests (more since v2, thanks to Simon's input)including: checkpatch, sparse, smatch, coccinelle, 32 bit and 64 bit builds tested on both X86, ARM 64 and emulated BE via qemu s390. We trigger performance testing in the CICD to catch performance regressions (currently only on the control path, but in the future for the datapath). Syzkaller runs 24/7 on dedicated hardware, originally we focussed only on memory sanitizer but recently added support for concurrency sanitizer. Before main releases we ensure each patch will compile on its own to help in git bisect and run the xmas tree tool. We eventually put the code via coverity. In addition we are working on a tool that will take a P4 program, run it through the compiler, and generate permutations of traffic patterns via symbolic execution that will test both positive and negative datapath code paths. The test generator tool is still work in progress and will be generated by the P4 compiler. Note: We have other code that test parallelization etc which we are trying to find a fit for in the kernel tree's testing infra. __Restating Our Requirements__ Our original intention was to target the TC crowd for both s/w and h/w offload. Essentially developers and ops people deploying TC based infra. More importantly the original intent for P4TC was to enable _ops folks_ more than devs (given code is being generated and doesn't need humans to write it). With TC we get whole "familiar" package of match-action pipeline abstraction++: from the control plane to the tooling infra, netlink messaging to s/w and h/w symbiosis, the autonomous kernel control, etc. The advantage is that we have a singular vendor-neutral interface via the kernel using well understood mechanisms based on deployment experience. 1) Supporting expressibility of universe set of P4 progs It is a must to support 100% of all possible P4 programs. In the past the eBPF verifier had to be worked around and even then there are cases where we couldnt avoid path explosion when branching is involved. Kfunc-ing solves these issues for us. Note, there are still challenges running all potential P4 programs at the XDP level - the solution to that is to have the compiler generate XDP based code only if it possible to map it to that layer. 2) Support for P4 HW and SW equivalence. This feature continues to work even in the presence of eBPF as the s/w datapath. There are cases of square-hole-round-peg scenarios but those are implementation issues we can live with. 3) Operational usability By maintaining the TC control plane (even in presence of eBPF datapath) runtime aspects remain unchanged. So for our target audience of folks who have deployed tc including offloads - the comfort zone is unchanged. There is some loss in operational usability because we now have more knobs: the extra compilation, loading and syncing of binaries, etc. IOW, I can no longer just ship someone a shell script in an email to say go run this and "myprog" will just work. 4) Operational and development Debuggability If something goes wrong, the tc craftsperson is now required to have additional knowledge of eBPF code and process. This applies to both the operational person as well as someone who wrote a driver. We dont believe this is solvable. 5) Opportunity for rapid prototyping of new ideas During the P4TC development phase something that came naturally was to often handcode the template scripts because the compiler backend (which is P4 arch specific) wasnt ready to generate certain things. Then you would read back the template and diff to ensure the kernel didn't get something wrong. So this started as a debug feature. During development, we wrote scripts that covered a range of P4 architectures(PSA, V1, etc) which required no kernel code changes. In its basic form it boils down to the old adage of a niche DSL script vs a compiled general purpose language such as eBPF. Given our target audience who know P4/TC, and understand our hooks, the shell script whose command set is more aligned to P4 is a natural fit compared to handcoding eBPF. Over time the debug feature morphed into: a) start by handcoding scripts then b) read it back and then c) generate the P4 code. It means one could start with the template scripts outside of the constraints of a P4 architecture spec(PNA/PSA) or even within a P4 architecture then test some ideas and eventually feed back the concepts to the compiler authors or modify or create a new P4 architecture and share with the P4 standards folks. To summarize in presence of eBPF: The debugging idea is still alive. One could dump, with proper tooling(bpftool for example), the loaded eBPF code and be able to check for differences. The concept of going back from whats in the kernel to P4 is a lot more difficult to implement mostly due to scoping of DSL vs general purpose. It may be lost. We have been thinking of ways to use BTF and embedding annotations in the eBPF code and binary but more thought is required and we welcome suggestions. 6) Performance It is clear you gain better performance for the datapath with eBPF. Refer to our results for the tests we did[1]. Note: for computationally complex programs this value diminishes i.e the gap between XDP and TC eBPF or even in some cases scriptable approach is not prominent; however, we do acknowledge there is an observable performance gain as expected (compiled vs interpreted approach). __Challenges__ 1) When we have either the parser or part/whole of s/w datapath running in XDP then we need to make sure that the instantiation at the TC level is aware. For this we reason we need a mechanism for ensuring that the XDP program stays alive. Unfortunately we dont have a clean way of doing this at the moment i.e the program could be removed under us by anyone with root access. For now the approach we are taking is to add a cookie field value at the XDP level and verify it at the TC level. We also recommend that the P4 prog is run under its own bpf mount. None of these schemes are going to save us from some malicious actor with root access; however, they are helpful in diminishing unintentional mistakes. A more foolproof approach is to allow token-based kerberos-like access control (who gets to load/unload progs regardless of root access). 2) Concept of tc block in XDP is _very tedious_ to implement. It would be nice if we can use concept there as well, since we expect P4 to work with many ports. 3) Right now we are using "packed" construct to enforce alignment in kfunc data exchange; but we're wondering if there is potential to use BTF to understand parameters and their offsets and encode this information at the compiler level. 4) At the moment we are creating a static buffer of 128B to retrieve the action parameters. If you have a lot of table entries and individual(non-shared) action instances with actions that require very little (or no) param space a lot of memory is wasted. There may also be cases where 128B may not be enough; (likely this is something we can teach the P4C compiler). If we can have dynamic pointers instead for kfunc fixed length parameterization then this issue is resolvable. 5) See "Restating Our Requirements" #5. We would really appreciate ideas/suggestions, etc. __References__ [1]https://github.com/p4tc-dev/docs/blob/main/p4-conference-2023/2023P4WorkshopP4TC.pdf [2]https://github.com/p4tc-dev/docs/blob/main/why-p4tc.md#historical-perspective-for-p4tc [3]https://2023p4workshop.sched.com/event/1KsAe/p4tc-linux-kernel-p4-implementation-approaches-and-evaluation [4]https://github.com/p4tc-dev/docs/blob/main/why-p4tc.md#so-why-p4-and-how-does-p4-help-here [5]https://lore.kernel.org/netdev/20230517110232.29349-3-jhs@mojatatu.com/T/#mf59be7abc5df3473cff3879c8cc3e2369c0640a6 [6]https://lore.kernel.org/netdev/20230517110232.29349-3-jhs@mojatatu.com/T/#m783cfd79e9d755cf0e7afc1a7d5404635a5b1919 [7]https://lore.kernel.org/netdev/20230517110232.29349-3-jhs@mojatatu.com/T/#ma8c84df0f7043d17b98f3d67aab0f4904c600469 [8]https://github.com/p4lang/p4c/tree/main/backends/tc Jamal Hadi Salim (23): net: sched: act_api: Introduce dynamic actions list net/sched: act_api: increase action kind string length net/sched: act_api: Update tc_action_ops to account for dynamic actions net/sched: act_api: export generic tc action searcher net/sched: act_api: add struct p4tc_action_ops as a parameter to lookup callback net: sched: act_api: Add support for preallocated dynamic action instances net: introduce rcu_replace_pointer_rtnl rtnl: add helper to check if group has listeners p4tc: add P4 data types p4tc: add pipeline create, get, update, delete p4tc: add header field create, get, delete, flush and dump p4tc: add action template create, update, delete, get, flush and dump p4tc: add table create, update, delete, get, flush and dump p4tc: add table entry create, update, get, delete, flush and dump p4tc: add set of P4TC table kfuncs p4tc: add P4 classifier p4tc: Add P4 extern interface selftests: tc-testing: add JSON introspection file directory for P4TC selftests: tc-testing: add P4TC pipeline control path tdc tests selftests: tc-testing: add P4TC action templates tdc tests selftests: tc-testing: add P4TC table control path tdc tests selftests: tc-testing: add P4TC table entries control path tdc tests MAINTAINERS: add p4tc entry MAINTAINERS | 15 + include/linux/bitops.h | 1 + include/linux/rtnetlink.h | 19 + include/net/act_api.h | 24 +- include/net/p4tc.h | 777 ++ include/net/p4tc_ext_api.h | 97 + include/net/p4tc_types.h | 87 + include/net/tc_act/p4tc.h | 27 + include/uapi/linux/p4tc.h | 393 + include/uapi/linux/p4tc_ext.h | 39 + include/uapi/linux/pkt_cls.h | 20 + include/uapi/linux/rtnetlink.h | 18 + net/sched/Kconfig | 21 + net/sched/Makefile | 3 + net/sched/act_api.c | 197 +- net/sched/cls_api.c | 2 +- net/sched/cls_p4.c | 508 ++ net/sched/p4tc/Makefile | 8 + net/sched/p4tc/p4tc_action.c | 2024 +++++ net/sched/p4tc/p4tc_bpf.c | 428 + net/sched/p4tc/p4tc_ext.c | 2035 +++++ net/sched/p4tc/p4tc_hdrfield.c | 579 ++ net/sched/p4tc/p4tc_parser_api.c | 150 + net/sched/p4tc/p4tc_pipeline.c | 733 ++ net/sched/p4tc/p4tc_runtime_api.c | 150 + net/sched/p4tc/p4tc_table.c | 1548 ++++ net/sched/p4tc/p4tc_tbl_entry.c | 2746 +++++++ net/sched/p4tc/p4tc_tmpl_api.c | 606 ++ net/sched/p4tc/p4tc_tmpl_ext.c | 2415 ++++++ net/sched/p4tc/p4tc_types.c | 1255 +++ net/sched/p4tc/trace.c | 10 + net/sched/p4tc/trace.h | 44 + security/selinux/nlmsgtab.c | 10 +- .../introspection-examples/example_pipe.json | 92 + .../tc-tests/p4tc/action_templates.json | 3937 ++++++++++ .../tc-testing/tc-tests/p4tc/pipeline.json | 1448 ++++ .../tc-testing/tc-tests/p4tc/table.json | 6944 +++++++++++++++++ .../tc-tests/p4tc/table_entries.json | 5872 ++++++++++++++ 38 files changed, 35241 insertions(+), 41 deletions(-) create mode 100644 include/net/p4tc.h create mode 100644 include/net/p4tc_ext_api.h create mode 100644 include/net/p4tc_types.h create mode 100644 include/net/tc_act/p4tc.h create mode 100644 include/uapi/linux/p4tc.h create mode 100644 include/uapi/linux/p4tc_ext.h create mode 100644 net/sched/cls_p4.c create mode 100644 net/sched/p4tc/Makefile create mode 100644 net/sched/p4tc/p4tc_action.c create mode 100644 net/sched/p4tc/p4tc_bpf.c create mode 100644 net/sched/p4tc/p4tc_ext.c create mode 100644 net/sched/p4tc/p4tc_hdrfield.c create mode 100644 net/sched/p4tc/p4tc_parser_api.c create mode 100644 net/sched/p4tc/p4tc_pipeline.c create mode 100644 net/sched/p4tc/p4tc_runtime_api.c create mode 100644 net/sched/p4tc/p4tc_table.c create mode 100644 net/sched/p4tc/p4tc_tbl_entry.c create mode 100644 net/sched/p4tc/p4tc_tmpl_api.c create mode 100644 net/sched/p4tc/p4tc_tmpl_ext.c create mode 100644 net/sched/p4tc/p4tc_types.c create mode 100644 net/sched/p4tc/trace.c create mode 100644 net/sched/p4tc/trace.h create mode 100644 tools/testing/selftests/tc-testing/introspection-examples/example_pipe.json create mode 100644 tools/testing/selftests/tc-testing/tc-tests/p4tc/action_templates.json create mode 100644 tools/testing/selftests/tc-testing/tc-tests/p4tc/pipeline.json create mode 100644 tools/testing/selftests/tc-testing/tc-tests/p4tc/table.json create mode 100644 tools/testing/selftests/tc-testing/tc-tests/p4tc/table_entries.json