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bb56cea9ab
As discussed with Maxim add a counter for true NoPad violations. This should help deployments catch unexpected padded records vs just control records which always need re-encryption. https: //lore.kernel.org/all/b111828e6ac34baad9f4e783127eba8344ac252d.camel@nvidia.com/ Signed-off-by: Jakub Kicinski <kuba@kernel.org>
289 lines
9.5 KiB
ReStructuredText
289 lines
9.5 KiB
ReStructuredText
.. _kernel_tls:
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==========
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Kernel TLS
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==========
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Overview
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========
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Transport Layer Security (TLS) is a Upper Layer Protocol (ULP) that runs over
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TCP. TLS provides end-to-end data integrity and confidentiality.
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User interface
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==============
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Creating a TLS connection
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-------------------------
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First create a new TCP socket and set the TLS ULP.
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.. code-block:: c
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sock = socket(AF_INET, SOCK_STREAM, 0);
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setsockopt(sock, SOL_TCP, TCP_ULP, "tls", sizeof("tls"));
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Setting the TLS ULP allows us to set/get TLS socket options. Currently
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only the symmetric encryption is handled in the kernel. After the TLS
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handshake is complete, we have all the parameters required to move the
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data-path to the kernel. There is a separate socket option for moving
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the transmit and the receive into the kernel.
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.. code-block:: c
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/* From linux/tls.h */
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struct tls_crypto_info {
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unsigned short version;
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unsigned short cipher_type;
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};
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struct tls12_crypto_info_aes_gcm_128 {
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struct tls_crypto_info info;
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unsigned char iv[TLS_CIPHER_AES_GCM_128_IV_SIZE];
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unsigned char key[TLS_CIPHER_AES_GCM_128_KEY_SIZE];
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unsigned char salt[TLS_CIPHER_AES_GCM_128_SALT_SIZE];
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unsigned char rec_seq[TLS_CIPHER_AES_GCM_128_REC_SEQ_SIZE];
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};
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struct tls12_crypto_info_aes_gcm_128 crypto_info;
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crypto_info.info.version = TLS_1_2_VERSION;
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crypto_info.info.cipher_type = TLS_CIPHER_AES_GCM_128;
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memcpy(crypto_info.iv, iv_write, TLS_CIPHER_AES_GCM_128_IV_SIZE);
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memcpy(crypto_info.rec_seq, seq_number_write,
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TLS_CIPHER_AES_GCM_128_REC_SEQ_SIZE);
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memcpy(crypto_info.key, cipher_key_write, TLS_CIPHER_AES_GCM_128_KEY_SIZE);
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memcpy(crypto_info.salt, implicit_iv_write, TLS_CIPHER_AES_GCM_128_SALT_SIZE);
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setsockopt(sock, SOL_TLS, TLS_TX, &crypto_info, sizeof(crypto_info));
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Transmit and receive are set separately, but the setup is the same, using either
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TLS_TX or TLS_RX.
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Sending TLS application data
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----------------------------
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After setting the TLS_TX socket option all application data sent over this
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socket is encrypted using TLS and the parameters provided in the socket option.
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For example, we can send an encrypted hello world record as follows:
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.. code-block:: c
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const char *msg = "hello world\n";
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send(sock, msg, strlen(msg));
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send() data is directly encrypted from the userspace buffer provided
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to the encrypted kernel send buffer if possible.
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The sendfile system call will send the file's data over TLS records of maximum
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length (2^14).
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.. code-block:: c
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file = open(filename, O_RDONLY);
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fstat(file, &stat);
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sendfile(sock, file, &offset, stat.st_size);
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TLS records are created and sent after each send() call, unless
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MSG_MORE is passed. MSG_MORE will delay creation of a record until
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MSG_MORE is not passed, or the maximum record size is reached.
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The kernel will need to allocate a buffer for the encrypted data.
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This buffer is allocated at the time send() is called, such that
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either the entire send() call will return -ENOMEM (or block waiting
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for memory), or the encryption will always succeed. If send() returns
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-ENOMEM and some data was left on the socket buffer from a previous
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call using MSG_MORE, the MSG_MORE data is left on the socket buffer.
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Receiving TLS application data
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------------------------------
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After setting the TLS_RX socket option, all recv family socket calls
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are decrypted using TLS parameters provided. A full TLS record must
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be received before decryption can happen.
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.. code-block:: c
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char buffer[16384];
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recv(sock, buffer, 16384);
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Received data is decrypted directly in to the user buffer if it is
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large enough, and no additional allocations occur. If the userspace
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buffer is too small, data is decrypted in the kernel and copied to
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userspace.
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``EINVAL`` is returned if the TLS version in the received message does not
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match the version passed in setsockopt.
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``EMSGSIZE`` is returned if the received message is too big.
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``EBADMSG`` is returned if decryption failed for any other reason.
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Send TLS control messages
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-------------------------
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Other than application data, TLS has control messages such as alert
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messages (record type 21) and handshake messages (record type 22), etc.
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These messages can be sent over the socket by providing the TLS record type
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via a CMSG. For example the following function sends @data of @length bytes
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using a record of type @record_type.
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.. code-block:: c
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/* send TLS control message using record_type */
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static int klts_send_ctrl_message(int sock, unsigned char record_type,
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void *data, size_t length)
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{
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struct msghdr msg = {0};
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int cmsg_len = sizeof(record_type);
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struct cmsghdr *cmsg;
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char buf[CMSG_SPACE(cmsg_len)];
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struct iovec msg_iov; /* Vector of data to send/receive into. */
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msg.msg_control = buf;
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msg.msg_controllen = sizeof(buf);
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cmsg = CMSG_FIRSTHDR(&msg);
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cmsg->cmsg_level = SOL_TLS;
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cmsg->cmsg_type = TLS_SET_RECORD_TYPE;
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cmsg->cmsg_len = CMSG_LEN(cmsg_len);
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*CMSG_DATA(cmsg) = record_type;
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msg.msg_controllen = cmsg->cmsg_len;
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msg_iov.iov_base = data;
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msg_iov.iov_len = length;
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msg.msg_iov = &msg_iov;
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msg.msg_iovlen = 1;
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return sendmsg(sock, &msg, 0);
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}
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Control message data should be provided unencrypted, and will be
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encrypted by the kernel.
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Receiving TLS control messages
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------------------------------
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TLS control messages are passed in the userspace buffer, with message
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type passed via cmsg. If no cmsg buffer is provided, an error is
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returned if a control message is received. Data messages may be
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received without a cmsg buffer set.
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.. code-block:: c
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char buffer[16384];
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char cmsg[CMSG_SPACE(sizeof(unsigned char))];
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struct msghdr msg = {0};
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msg.msg_control = cmsg;
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msg.msg_controllen = sizeof(cmsg);
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struct iovec msg_iov;
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msg_iov.iov_base = buffer;
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msg_iov.iov_len = 16384;
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msg.msg_iov = &msg_iov;
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msg.msg_iovlen = 1;
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int ret = recvmsg(sock, &msg, 0 /* flags */);
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struct cmsghdr *cmsg = CMSG_FIRSTHDR(&msg);
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if (cmsg->cmsg_level == SOL_TLS &&
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cmsg->cmsg_type == TLS_GET_RECORD_TYPE) {
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int record_type = *((unsigned char *)CMSG_DATA(cmsg));
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// Do something with record_type, and control message data in
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// buffer.
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//
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// Note that record_type may be == to application data (23).
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} else {
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// Buffer contains application data.
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}
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recv will never return data from mixed types of TLS records.
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Integrating in to userspace TLS library
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---------------------------------------
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At a high level, the kernel TLS ULP is a replacement for the record
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layer of a userspace TLS library.
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A patchset to OpenSSL to use ktls as the record layer is
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`here <https://github.com/Mellanox/openssl/commits/tls_rx2>`_.
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`An example <https://github.com/ktls/af_ktls-tool/commits/RX>`_
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of calling send directly after a handshake using gnutls.
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Since it doesn't implement a full record layer, control
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messages are not supported.
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Optional optimizations
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----------------------
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There are certain condition-specific optimizations the TLS ULP can make,
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if requested. Those optimizations are either not universally beneficial
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or may impact correctness, hence they require an opt-in.
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All options are set per-socket using setsockopt(), and their
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state can be checked using getsockopt() and via socket diag (``ss``).
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TLS_TX_ZEROCOPY_RO
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~~~~~~~~~~~~~~~~~~
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For device offload only. Allow sendfile() data to be transmitted directly
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to the NIC without making an in-kernel copy. This allows true zero-copy
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behavior when device offload is enabled.
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The application must make sure that the data is not modified between being
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submitted and transmission completing. In other words this is mostly
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applicable if the data sent on a socket via sendfile() is read-only.
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Modifying the data may result in different versions of the data being used
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for the original TCP transmission and TCP retransmissions. To the receiver
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this will look like TLS records had been tampered with and will result
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in record authentication failures.
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TLS_RX_EXPECT_NO_PAD
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~~~~~~~~~~~~~~~~~~~~
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TLS 1.3 only. Expect the sender to not pad records. This allows the data
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to be decrypted directly into user space buffers with TLS 1.3.
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This optimization is safe to enable only if the remote end is trusted,
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otherwise it is an attack vector to doubling the TLS processing cost.
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If the record decrypted turns out to had been padded or is not a data
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record it will be decrypted again into a kernel buffer without zero copy.
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Such events are counted in the ``TlsDecryptRetry`` statistic.
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Statistics
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==========
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TLS implementation exposes the following per-namespace statistics
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(``/proc/net/tls_stat``):
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- ``TlsCurrTxSw``, ``TlsCurrRxSw`` -
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number of TX and RX sessions currently installed where host handles
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cryptography
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- ``TlsCurrTxDevice``, ``TlsCurrRxDevice`` -
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number of TX and RX sessions currently installed where NIC handles
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cryptography
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- ``TlsTxSw``, ``TlsRxSw`` -
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number of TX and RX sessions opened with host cryptography
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- ``TlsTxDevice``, ``TlsRxDevice`` -
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number of TX and RX sessions opened with NIC cryptography
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- ``TlsDecryptError`` -
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record decryption failed (e.g. due to incorrect authentication tag)
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- ``TlsDeviceRxResync`` -
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number of RX resyncs sent to NICs handling cryptography
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- ``TlsDecryptRetry`` -
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number of RX records which had to be re-decrypted due to
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``TLS_RX_EXPECT_NO_PAD`` mis-prediction. Note that this counter will
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also increment for non-data records.
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- ``TlsRxNoPadViolation`` -
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number of data RX records which had to be re-decrypted due to
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``TLS_RX_EXPECT_NO_PAD`` mis-prediction.
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