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author | David S. Miller <davem@davemloft.net> | 2018-05-01 15:42:48 +0200 |
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committer | David S. Miller <davem@davemloft.net> | 2018-05-01 15:42:48 +0200 |
commit | e33200bc01a6cfe73aa022cd4af92c1501c1e09a (patch) | |
tree | ea390cef430d0a06d3a2e128933922dd5bb62434 /lib/kobject_uevent.c | |
parent | Merge branch '40GbE' of git://git.kernel.org/pub/scm/linux/kernel/git/jkirshe... (diff) | |
parent | MAINTAINERS: Update TLS maintainers (diff) | |
download | linux-e33200bc01a6cfe73aa022cd4af92c1501c1e09a.tar.xz linux-e33200bc01a6cfe73aa022cd4af92c1501c1e09a.zip |
Merge branch 'tls-offload-netdev-and-mlx5-support'
Boris Pismenny says:
====================
TLS offload, netdev & MLX5 support
The following series provides TLS TX inline crypto offload.
v1->v2:
- Added IS_ENABLED(CONFIG_TLS_DEVICE) and a STATIC_KEY for icsk_clean_acked
- File license fix
- Fix spelling, comment by DaveW
- Move memory allocations out of tls_set_device_offload and other misc fixes,
comments by Kiril.
v2->v3:
- Reversed xmas tree where needed and style fixes
- Removed the need for skb_page_frag_refill, per Eric's comment
- IPv6 dependency fixes
v3->v4:
- Remove "inline" from functions in C files
- Make clean_acked_data_enabled a static variable and add enable/disable functions to control it.
- Remove unnecessary variable initialization mentioned by ShannonN
- Rebase over TLS RX
- Refactor the tls_software_fallback to reduce the number of variables mentioned by KirilT
v4->v5:
- Add missing CONFIG_TLS_DEVICE
v5->v6:
- Move changes to the software implementation into a seperate patch
- Fix some checkpatch warnings
- GPL export the enable/disable clean_acked_data functions
v6->v7:
- Use the dst_entry to obtain the netdev in dev_get_by_index
- Remove the IPv6 patch since it is redundent now
v7->v8:
- Fix a merge conflict in mlx5 header
v8->v9:
- Fix false -Wmaybe-uninitialized warning
- Fix empty space in the end of new files
v9->v10:
- Remove default "n" in net/Kconfig
This series adds a generic infrastructure to offload TLS crypto to a
network devices. It enables the kernel TLS socket to skip encryption and
authentication operations on the transmit side of the data path. Leaving
those computationally expensive operations to the NIC.
The NIC offload infrastructure builds TLS records and pushes them to the
TCP layer just like the SW KTLS implementation and using the same API.
TCP segmentation is mostly unaffected. Currently the only exception is
that we prevent mixed SKBs where only part of the payload requires
offload. In the future we are likely to add a similar restriction
following a change cipher spec record.
The notable differences between SW KTLS and NIC offloaded TLS
implementations are as follows:
1. The offloaded implementation builds "plaintext TLS record", those
records contain plaintext instead of ciphertext and place holder bytes
instead of authentication tags.
2. The offloaded implementation maintains a mapping from TCP sequence
number to TLS records. Thus given a TCP SKB sent from a NIC offloaded
TLS socket, we can use the tls NIC offload infrastructure to obtain
enough context to encrypt the payload of the SKB.
A TLS record is released when the last byte of the record is ack'ed,
this is done through the new icsk_clean_acked callback.
The infrastructure should be extendable to support various NIC offload
implementations. However it is currently written with the
implementation below in mind:
The NIC assumes that packets from each offloaded stream are sent as
plaintext and in-order. It keeps track of the TLS records in the TCP
stream. When a packet marked for offload is transmitted, the NIC
encrypts the payload in-place and puts authentication tags in the
relevant place holders.
The responsibility for handling out-of-order packets (i.e. TCP
retransmission, qdisc drops) falls on the netdev driver.
The netdev driver keeps track of the expected TCP SN from the NIC's
perspective. If the next packet to transmit matches the expected TCP
SN, the driver advances the expected TCP SN, and transmits the packet
with TLS offload indication.
If the next packet to transmit does not match the expected TCP SN. The
driver calls the TLS layer to obtain the TLS record that includes the
TCP of the packet for transmission. Using this TLS record, the driver
posts a work entry on the transmit queue to reconstruct the NIC TLS
state required for the offload of the out-of-order packet. It updates
the expected TCP SN accordingly and transmit the now in-order packet.
The same queue is used for packet transmission and TLS context
reconstruction to avoid the need for flushing the transmit queue before
issuing the context reconstruction request.
Expected TCP SN is accessed without a lock, under the assumption that
TCP doesn't transmit SKBs from different TX queue concurrently.
If packets are rerouted to a different netdevice, then a software
fallback routine handles encryption.
Paper: https://www.netdevconf.org/1.2/papers/netdevconf-TLS.pdf
====================
Signed-off-by: David S. Miller <davem@davemloft.net>
Diffstat (limited to 'lib/kobject_uevent.c')
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