3cc28001a3
Unmatched double quotation mark is fixed.
Fixes: ba7b86b141
("doc: add l2fwd-crypto sample app guide")
Cc: stable@dpdk.org
Signed-off-by: Xiao Wang <xiao.w.wang@intel.com>
Acked-by: Akhil Goyal <akhil.goyal@nxp.com>
485 lines
16 KiB
ReStructuredText
485 lines
16 KiB
ReStructuredText
.. SPDX-License-Identifier: BSD-3-Clause
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Copyright(c) 2016-2017 Intel Corporation.
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.. _l2_fwd_crypto_app:
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L2 Forwarding with Crypto Sample Application
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============================================
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The L2 Forwarding with Crypto (l2fwd-crypto) sample application is a simple example of packet processing using
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the Data Plane Development Kit (DPDK), in conjunction with the Cryptodev library.
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Overview
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--------
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The L2 Forwarding with Crypto sample application performs a crypto operation (cipher/hash)
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specified by the user from command line (or using the default values),
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with a crypto device capable of doing that operation,
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for each packet that is received on a RX_PORT and performs L2 forwarding.
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The destination port is the adjacent port from the enabled portmask, that is,
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if the first four ports are enabled (portmask 0xf),
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ports 0 and 1 forward into each other, and ports 2 and 3 forward into each other.
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Also, if MAC addresses updating is enabled, the MAC addresses are affected as follows:
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* The source MAC address is replaced by the TX_PORT MAC address
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* The destination MAC address is replaced by 02:00:00:00:00:TX_PORT_ID
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Compiling the Application
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-------------------------
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To compile the sample application see :doc:`compiling`.
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The application is located in the ``l2fwd-crypt`` sub-directory.
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Running the Application
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-----------------------
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The application requires a number of command line options:
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.. code-block:: console
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./build/l2fwd-crypto [EAL options] -- [-p PORTMASK] [-q NQ] [-s] [-T PERIOD] /
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[--cdev_type HW/SW/ANY] [--chain HASH_CIPHER/CIPHER_HASH/CIPHER_ONLY/HASH_ONLY/AEAD] /
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[--cipher_algo ALGO] [--cipher_op ENCRYPT/DECRYPT] [--cipher_key KEY] /
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[--cipher_key_random_size SIZE] [--cipher_iv IV] [--cipher_iv_random_size SIZE] /
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[--auth_algo ALGO] [--auth_op GENERATE/VERIFY] [--auth_key KEY] /
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[--auth_key_random_size SIZE] [--auth_iv IV] [--auth_iv_random_size SIZE] /
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[--aead_algo ALGO] [--aead_op ENCRYPT/DECRYPT] [--aead_key KEY] /
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[--aead_key_random_size SIZE] [--aead_iv] [--aead_iv_random_size SIZE] /
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[--aad AAD] [--aad_random_size SIZE] /
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[--digest size SIZE] [--sessionless] [--cryptodev_mask MASK] /
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[--mac-updating] [--no-mac-updating]
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where,
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* p PORTMASK: A hexadecimal bitmask of the ports to configure (default is all the ports)
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* q NQ: A number of queues (=ports) per lcore (default is 1)
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* s: manage all ports from single core
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* T PERIOD: statistics will be refreshed each PERIOD seconds
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(0 to disable, 10 default, 86400 maximum)
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* cdev_type: select preferred crypto device type: HW, SW or anything (ANY)
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(default is ANY)
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* chain: select the operation chaining to perform: Cipher->Hash (CIPHER_HASH),
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Hash->Cipher (HASH_CIPHER), Cipher (CIPHER_ONLY), Hash (HASH_ONLY)
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or AEAD (AEAD)
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(default is Cipher->Hash)
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* cipher_algo: select the ciphering algorithm (default is aes-cbc)
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* cipher_op: select the ciphering operation to perform: ENCRYPT or DECRYPT
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(default is ENCRYPT)
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* cipher_key: set the ciphering key to be used. Bytes has to be separated with ":"
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* cipher_key_random_size: set the size of the ciphering key,
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which will be generated randomly.
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Note that if --cipher_key is used, this will be ignored.
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* cipher_iv: set the cipher IV to be used. Bytes has to be separated with ":"
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* cipher_iv_random_size: set the size of the cipher IV, which will be generated randomly.
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Note that if --cipher_iv is used, this will be ignored.
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* auth_algo: select the authentication algorithm (default is sha1-hmac)
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* auth_op: select the authentication operation to perform: GENERATE or VERIFY
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(default is GENERATE)
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* auth_key: set the authentication key to be used. Bytes has to be separated with ":"
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* auth_key_random_size: set the size of the authentication key,
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which will be generated randomly.
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Note that if --auth_key is used, this will be ignored.
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* auth_iv: set the auth IV to be used. Bytes has to be separated with ":"
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* auth_iv_random_size: set the size of the auth IV, which will be generated randomly.
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Note that if --auth_iv is used, this will be ignored.
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* aead_algo: select the AEAD algorithm (default is aes-gcm)
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* aead_op: select the AEAD operation to perform: ENCRYPT or DECRYPT
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(default is ENCRYPT)
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* aead_key: set the AEAD key to be used. Bytes has to be separated with ":"
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* aead_key_random_size: set the size of the AEAD key,
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which will be generated randomly.
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Note that if --aead_key is used, this will be ignored.
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* aead_iv: set the AEAD IV to be used. Bytes has to be separated with ":"
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* aead_iv_random_size: set the size of the AEAD IV, which will be generated randomly.
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Note that if --aead_iv is used, this will be ignored.
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* aad: set the AAD to be used. Bytes has to be separated with ":"
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* aad_random_size: set the size of the AAD, which will be generated randomly.
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Note that if --aad is used, this will be ignored.
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* digest_size: set the size of the digest to be generated/verified.
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* sessionless: no crypto session will be created.
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* cryptodev_mask: A hexadecimal bitmask of the cryptodevs to be used by the
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application.
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(default is all cryptodevs).
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* [no-]mac-updating: Enable or disable MAC addresses updating (enabled by default).
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The application requires that crypto devices capable of performing
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the specified crypto operation are available on application initialization.
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This means that HW crypto device/s must be bound to a DPDK driver or
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a SW crypto device/s (virtual crypto PMD) must be created (using --vdev).
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To run the application in linux environment with 2 lcores, 2 ports and 2 crypto devices, issue the command:
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.. code-block:: console
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$ ./build/l2fwd-crypto -l 0-1 -n 4 --vdev "crypto_aesni_mb0" \
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--vdev "crypto_aesni_mb1" -- -p 0x3 --chain CIPHER_HASH \
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--cipher_op ENCRYPT --cipher_algo aes-cbc \
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--cipher_key 00:01:02:03:04:05:06:07:08:09:0a:0b:0c:0d:0e:0f \
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--auth_op GENERATE --auth_algo aes-xcbc-mac \
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--auth_key 10:11:12:13:14:15:16:17:18:19:1a:1b:1c:1d:1e:1f
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Refer to the *DPDK Getting Started Guide* for general information on running applications
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and the Environment Abstraction Layer (EAL) options.
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.. Note::
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* The ``l2fwd-crypto`` sample application requires IPv4 packets for crypto operation.
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* If multiple Ethernet ports is passed, then equal number of crypto devices are to be passed.
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* All crypto devices shall use the same session.
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Explanation
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-----------
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The L2 forward with Crypto application demonstrates the performance of a crypto operation
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on a packet received on a RX PORT before forwarding it to a TX PORT.
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The following figure illustrates a sample flow of a packet in the application,
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from reception until transmission.
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.. _figure_l2_fwd_encrypt_flow:
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.. figure:: img/l2_fwd_encrypt_flow.*
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Encryption flow Through the L2 Forwarding with Crypto Application
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The following sections provide some explanation of the application.
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Crypto operation specification
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~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
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All the packets received in all the ports get transformed by the crypto device/s
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(ciphering and/or authentication).
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The crypto operation to be performed on the packet is parsed from the command line
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(go to "Running the Application" section for all the options).
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If no parameter is passed, the default crypto operation is:
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* Encryption with AES-CBC with 128 bit key.
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* Authentication with SHA1-HMAC (generation).
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* Keys, IV and AAD are generated randomly.
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There are two methods to pass keys, IV and ADD from the command line:
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* Passing the full key, separated bytes by ":"::
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--cipher_key 00:11:22:33:44
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* Passing the size, so key is generated randomly::
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--cipher_key_random_size 16
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**Note**:
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If full key is passed (first method) and the size is passed as well (second method),
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the latter will be ignored.
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Size of these keys are checked (regardless the method), before starting the app,
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to make sure that it is supported by the crypto devices.
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Crypto device initialization
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~~~~~~~~~~~~~~~~~~~~~~~~~~~~
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Once the encryption operation is defined, crypto devices are initialized.
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The crypto devices must be either bound to a DPDK driver (if they are physical devices)
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or created using the EAL option --vdev (if they are virtual devices),
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when running the application.
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The initialize_cryptodevs() function performs the device initialization.
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It iterates through the list of the available crypto devices and
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check which ones are capable of performing the operation.
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Each device has a set of capabilities associated with it,
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which are stored in the device info structure, so the function checks if the operation
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is within the structure of each device.
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The following code checks if the device supports the specified cipher algorithm
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(similar for the authentication algorithm):
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.. code-block:: c
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/* Check if device supports cipher algo */
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i = 0;
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opt_cipher_algo = options->cipher_xform.cipher.algo;
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cap = &dev_info.capabilities[i];
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while (cap->op != RTE_CRYPTO_OP_TYPE_UNDEFINED) {
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cap_cipher_algo = cap->sym.cipher.algo;
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if (cap->sym.xform_type ==
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RTE_CRYPTO_SYM_XFORM_CIPHER) {
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if (cap_cipher_algo == opt_cipher_algo) {
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if (check_type(options, &dev_info) == 0)
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break;
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}
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}
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cap = &dev_info.capabilities[++i];
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}
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If a capable crypto device is found, key sizes are checked to see if they are supported
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(cipher key and IV for the ciphering):
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.. code-block:: c
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/*
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* Check if length of provided cipher key is supported
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* by the algorithm chosen.
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*/
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if (options->ckey_param) {
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if (check_supported_size(
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options->cipher_xform.cipher.key.length,
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cap->sym.cipher.key_size.min,
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cap->sym.cipher.key_size.max,
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cap->sym.cipher.key_size.increment)
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!= 0) {
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printf("Unsupported cipher key length\n");
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return -1;
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}
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/*
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* Check if length of the cipher key to be randomly generated
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* is supported by the algorithm chosen.
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*/
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} else if (options->ckey_random_size != -1) {
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if (check_supported_size(options->ckey_random_size,
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cap->sym.cipher.key_size.min,
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cap->sym.cipher.key_size.max,
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cap->sym.cipher.key_size.increment)
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!= 0) {
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printf("Unsupported cipher key length\n");
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return -1;
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}
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options->cipher_xform.cipher.key.length =
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options->ckey_random_size;
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/* No size provided, use minimum size. */
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} else
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options->cipher_xform.cipher.key.length =
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cap->sym.cipher.key_size.min;
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After all the checks, the device is configured and it is added to the
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crypto device list.
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**Note**:
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The number of crypto devices that supports the specified crypto operation
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must be at least the number of ports to be used.
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Session creation
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~~~~~~~~~~~~~~~~
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The crypto operation has a crypto session associated to it, which contains
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information such as the transform chain to perform (e.g. ciphering then hashing),
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pointers to the keys, lengths... etc.
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This session is created and is later attached to the crypto operation:
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.. code-block:: c
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static struct rte_cryptodev_sym_session *
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initialize_crypto_session(struct l2fwd_crypto_options *options,
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uint8_t cdev_id)
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{
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struct rte_crypto_sym_xform *first_xform;
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struct rte_cryptodev_sym_session *session;
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uint8_t socket_id = rte_cryptodev_socket_id(cdev_id);
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struct rte_mempool *sess_mp = session_pool_socket[socket_id];
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if (options->xform_chain == L2FWD_CRYPTO_AEAD) {
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first_xform = &options->aead_xform;
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} else if (options->xform_chain == L2FWD_CRYPTO_CIPHER_HASH) {
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first_xform = &options->cipher_xform;
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first_xform->next = &options->auth_xform;
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} else if (options->xform_chain == L2FWD_CRYPTO_HASH_CIPHER) {
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first_xform = &options->auth_xform;
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first_xform->next = &options->cipher_xform;
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} else if (options->xform_chain == L2FWD_CRYPTO_CIPHER_ONLY) {
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first_xform = &options->cipher_xform;
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} else {
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first_xform = &options->auth_xform;
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}
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session = rte_cryptodev_sym_session_create(sess_mp);
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if (session == NULL)
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return NULL;
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if (rte_cryptodev_sym_session_init(cdev_id, session,
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first_xform, sess_mp) < 0)
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return NULL;
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return session;
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}
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...
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port_cparams[i].session = initialize_crypto_session(options,
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port_cparams[i].dev_id);
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Crypto operation creation
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~~~~~~~~~~~~~~~~~~~~~~~~~
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Given N packets received from a RX PORT, N crypto operations are allocated
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and filled:
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.. code-block:: c
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if (nb_rx) {
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/*
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* If we can't allocate a crypto_ops, then drop
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* the rest of the burst and dequeue and
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* process the packets to free offload structs
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*/
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if (rte_crypto_op_bulk_alloc(
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l2fwd_crypto_op_pool,
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RTE_CRYPTO_OP_TYPE_SYMMETRIC,
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ops_burst, nb_rx) !=
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nb_rx) {
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for (j = 0; j < nb_rx; j++)
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rte_pktmbuf_free(pkts_burst[i]);
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nb_rx = 0;
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}
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After filling the crypto operation (including session attachment),
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the mbuf which will be transformed is attached to it::
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op->sym->m_src = m;
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Since no destination mbuf is set, the source mbuf will be overwritten
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after the operation is done (in-place).
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Crypto operation enqueuing/dequeuing
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~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
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Once the operation has been created, it has to be enqueued in one of the crypto devices.
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Before doing so, for performance reasons, the operation stays in a buffer.
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When the buffer has enough operations (MAX_PKT_BURST), they are enqueued in the device,
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which will perform the operation at that moment:
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.. code-block:: c
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static int
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l2fwd_crypto_enqueue(struct rte_crypto_op *op,
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struct l2fwd_crypto_params *cparams)
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{
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unsigned lcore_id, len;
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struct lcore_queue_conf *qconf;
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lcore_id = rte_lcore_id();
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qconf = &lcore_queue_conf[lcore_id];
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len = qconf->op_buf[cparams->dev_id].len;
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qconf->op_buf[cparams->dev_id].buffer[len] = op;
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len++;
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/* enough ops to be sent */
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if (len == MAX_PKT_BURST) {
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l2fwd_crypto_send_burst(qconf, MAX_PKT_BURST, cparams);
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len = 0;
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}
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qconf->op_buf[cparams->dev_id].len = len;
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return 0;
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}
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...
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static int
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l2fwd_crypto_send_burst(struct lcore_queue_conf *qconf, unsigned n,
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struct l2fwd_crypto_params *cparams)
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{
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struct rte_crypto_op **op_buffer;
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unsigned ret;
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op_buffer = (struct rte_crypto_op **)
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qconf->op_buf[cparams->dev_id].buffer;
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ret = rte_cryptodev_enqueue_burst(cparams->dev_id,
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cparams->qp_id, op_buffer, (uint16_t) n);
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crypto_statistics[cparams->dev_id].enqueued += ret;
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if (unlikely(ret < n)) {
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crypto_statistics[cparams->dev_id].errors += (n - ret);
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do {
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rte_pktmbuf_free(op_buffer[ret]->sym->m_src);
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rte_crypto_op_free(op_buffer[ret]);
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} while (++ret < n);
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}
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return 0;
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}
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After this, the operations are dequeued from the device, and the transformed mbuf
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is extracted from the operation. Then, the operation is freed and the mbuf is
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forwarded as it is done in the L2 forwarding application.
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.. code-block:: c
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/* Dequeue packets from Crypto device */
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do {
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nb_rx = rte_cryptodev_dequeue_burst(
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cparams->dev_id, cparams->qp_id,
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ops_burst, MAX_PKT_BURST);
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crypto_statistics[cparams->dev_id].dequeued +=
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nb_rx;
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/* Forward crypto'd packets */
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for (j = 0; j < nb_rx; j++) {
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m = ops_burst[j]->sym->m_src;
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rte_crypto_op_free(ops_burst[j]);
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l2fwd_simple_forward(m, portid);
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}
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} while (nb_rx == MAX_PKT_BURST);
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