18327be5d4
A NAT sub-plugin doing statically configured match/rewrite on IP4 input or output.
It's stateless (no connection tracking).
Currently it supports rewriting of SA, DA and TCP/UDP ports.
It should be simple to add new rewrites if required.
API:
pnat_binding_add, pnat_binding_del, pnat_bindings_get, pnat_interfaces_get
CLI:
set pnat translation interface <name> match <5-tuple> rewrite <5-tuple> {in|out} [del]
show pnat translations
show pnat interfaces
Trying a new C based unit testing scheme. Where the graph node is tested
in isolation. See pnat/pnat_test.c.
Also added new cmake targets to generate coverage directly.
E.g.:
make test_pnat-ccov-report
File '/vpp/sdnat/src/plugins/nat/pnat/pnat.c':
Name Regions Miss Cover Lines Miss Cover
------------------------------------------------------------------------------------
pnat_interface_by_sw_if_index 39 8 79.49% 13 0 100.00%
pnat_instructions_from_mask 9 0 100.00% 13 0 100.00%
pnat_binding_add 64 8 87.50% 31 2 93.55%
pnat_flow_lookup 4 4 0.00% 10 10 0.00%
pnat_binding_attach 104 75 27.88% 33 6 81.82%
pnat_binding_detach 30 5 83.33% 23 2 91.30%
pnat_binding_del 97 33 65.98% 17 3 82.35%
pnat.c:pnat_calc_key_from_5tuple 9 1 88.89% 14 1 92.86%
pnat.c:pnat_interface_check_mask 10 2 80.00% 11 2 81.82%
pnat.c:pnat_enable 5 0 100.00% 11 0 100.00%
pnat.c:pnat_enable_interface 107 26 75.70% 60 15 75.00%
pnat.c:pnat_disable_interface 91 30 67.03% 32 7 78.12%
pnat.c:pnat_disable 7 2 71.43% 13 7 46.15%
------------------------------------------------------------------------------------
TOTAL 576 194 66.32% 281 55 80.43%
File '/vpp/sdnat/src/plugins/nat/pnat/pnat_node.h':
Name Regions Miss Cover Lines Miss Cover
------------------------------------------------------------------------------------
pnat_test.c:pnat_node_inline 67 11 83.58% 115 1 99.13%
pnat_test.c:pnat_calc_key 9 2 77.78% 14 2 85.71%
pnat_test.c:pnat_rewrite_ip4 55 11 80.00% 60 12 80.00%
pnat_test.c:format_pnat_trace 1 1 0.00% 12 12 0.00%
pnat_node.c:pnat_node_inline 63 63 0.00% 115 115 0.00%
pnat_node.c:pnat_calc_key 9 9 0.00% 14 14 0.00%
pnat_node.c:pnat_rewrite_ip4 55 55 0.00% 60 60 0.00%
pnat_node.c:format_pnat_trace 5 5 0.00% 12 12 0.00%
------------------------------------------------------------------------------------
TOTAL 264 157 40.53% 402 228 43.28%
Type: feature
Change-Id: I9c897f833603054a8303e7369ebff6512517c9e0
Signed-off-by: Ole Troan <ot@cisco.com>
Vector Packet Processing
Introduction
The VPP platform is an extensible framework that provides out-of-the-box production quality switch/router functionality. It is the open source version of Cisco's Vector Packet Processing (VPP) technology: a high performance, packet-processing stack that can run on commodity CPUs.
The benefits of this implementation of VPP are its high performance, proven technology, its modularity and flexibility, and rich feature set.
For more information on VPP and its features please visit the FD.io website and What is VPP? pages.
Changes
Details of the changes leading up to this version of VPP can be found under @ref release_notes.
Directory layout
| Directory name | Description |
|---|---|
| build-data | Build metadata |
| build-root | Build output directory |
| doxygen | Documentation generator configuration |
| dpdk | DPDK patches and build infrastructure |
| @ref extras/libmemif | Client library for memif |
| @ref src/examples | VPP example code |
| @ref src/plugins | VPP bundled plugins directory |
| @ref src/svm | Shared virtual memory allocation library |
| src/tests | Standalone tests (not part of test harness) |
| src/vat | VPP API test program |
| @ref src/vlib | VPP application library |
| @ref src/vlibapi | VPP API library |
| @ref src/vlibmemory | VPP Memory management |
| @ref src/vnet | VPP networking |
| @ref src/vpp | VPP application |
| @ref src/vpp-api | VPP application API bindings |
| @ref src/vppinfra | VPP core library |
| @ref src/vpp/api | Not-yet-relocated API bindings |
| test | Unit tests and Python test harness |
Getting started
In general anyone interested in building, developing or running VPP should consult the VPP wiki for more complete documentation.
In particular, readers are recommended to take a look at [Pulling, Building, Running, Hacking, Pushing](https://wiki.fd.io/view/VPP/Pulling,_Building,_Run ning,_Hacking_and_Pushing_VPP_Code) which provides extensive step-by-step coverage of the topic.
For the impatient, some salient information is distilled below.
Quick-start: On an existing Linux host
To install system dependencies, build VPP and then install it, simply run the
build script. This should be performed a non-privileged user with sudo
access from the project base directory:
./extras/vagrant/build.sh
If you want a more fine-grained approach because you intend to do some
development work, the Makefile in the root directory of the source tree
provides several convenience shortcuts as make targets that may be of
interest. To see the available targets run:
make
Quick-start: Vagrant
The directory extras/vagrant contains a VagrantFile and supporting
scripts to bootstrap a working VPP inside a Vagrant-managed Virtual Machine.
This VM can then be used to test concepts with VPP or as a development
platform to extend VPP. Some obvious caveats apply when using a VM for VPP
since its performance will never match that of bare metal; if your work is
timing or performance sensitive, consider using bare metal in addition or
instead of the VM.
For this to work you will need a working installation of Vagrant. Instructions for this can be found [on the Setting up Vagrant wiki page] (https://wiki.fd.io/view/DEV/Setting_Up_Vagrant).
More information
Several modules provide documentation, see @subpage user_doc for more end-user-oriented information. Also see @subpage dev_doc for developer notes.
Visit the VPP wiki for details on more advanced building strategies and other development notes.
Test Framework
There is PyDoc generated documentation available for the VPP test framework. See @ref test_framework_doc for details.