Intel® QuickAssist Technology OpenSSL* Engine (QAT_Engine) supports acceleration for both hardware as well as optimized software based on vectorized instructions. This change starting with the 3rd Generation Intel® Xeon® Scalable Processors family provides users more options to accelerate their workloads. The QAT OpenSSL* engine now supports the ability to accelerate from the stand OpenSSL* to basic Intel instruction set, to either Hardware acceleration path (via the qat_hw path) or via the optimized SW path (qat_sw lib). This document details the capabilities and interfaces for both internal libraries which maintaining the cohesiveness of being all packaged up with the QAT_Engine.
The image below illustrates the high-level software architecture of the QAT_Engine. Applications such as NGINX and HAProxy are common applications which interfaces to OpenSSL*. OpenSSL* is a toolkit for TLS/SSL protocols and has developed a modular system to plugin device-specific engines starting with version 1.1.0. As mentioned above, within the QAT_Engine are two separate internal entities by which acceleration can be performed. Depending on your particular use case, the QAT_Engine can be configured to meet your specific acceleration needs. This document details the capabilities of the QAT engine as well as the limitations. Both the hardware and software requirements are explained followed by detailed instructions how to install QAT_Engine. If you have any issues integrating the QAT_Engine, we’ve added a troubleshooting section.
Features of the QAT_Engine are described here.
Limitations and known issues for the QAT_Engine are described here.
Installation consists of the following:
Install Prerequisites
Switch to Build the Intel® QuickAssist Technology OpenSSL* Engine - Example 5 and use the make depend
target to clone and build the latest compatible versions of the dependant libraries automatically based on the target in the QAT Engine build configure.
qat_hw Prerequisites
Install the Intel® QuickAssist Technology Driver using instructions from the Getting Started Guide
Platform | Getting Started Guide |
---|---|
Intel® Xeon® with Intel® C62X Series Chipset Intel® Atom™ Processor with Intel® C3xx series Intel® Communications Chipset 8925 to 8955 Series |
Intel® QAT Software for Linux* - Getting Started Guide Hardware v1.x CE Release |
Intel® Xeon® Scalable Processor family with Intel® QAT Gen4/Gen4m | Intel® QAT Software for Linux* - Getting Started Guide Hardware v2.0 |
Other technical collaterals of the Intel® QuickAssist Technology driver can be found in the below page.
The Intel® QAT API requires many of the data structures (those that will be passed to the hardware) to be allocated in contiguous pinned memory in order to support DMA operations. You must either supply your own contiguous memory driver and make changes to the engine to make use of it or use one of the following drivers:
The Intel® QAT Driver for QAT_HW comes with its own contiguous pinned memory driver that is compatible with the Intel® QAT OpenSSL* Engine. The USDM component is of a higher quality than the qat_contig_mem driver provided within the Intel® QAT OpenSSL* Engine, and is the preferred option. The USDM component is used by the Intel® QAT Driver itself, and also has the following additional features:
- Support for virtualization
- Support for configurable slab sizes
- Support for configurable secure freeing of memory (overwrite with zeros)
- Support for configurable slab caching
- Support for newer kernels
- Support for thread specific memory to avoid locks (QAT_HW Version 1.7 & 1.8 only)
The USDM component is located within the Intel® QAT Driver for QAT_HW
source code in the following subdirectory: quickassist/utilities/libusdm_drv
.
As the USDM component is also used by the QAT_HW driver itself it will have
already been built when the driver was built. It may also already be loaded as
well, and you can check by running lsmod
and looking for usdm_drv in the list.
If not present it can be loaded as follows:
modprobe usdm_drv.ko
The USDM thread specific memory can be enabled in QAT_HW driver using the below configure flags in driver build which is only needed for multithreaded application for performance improvement. This is supported from version 4.20 of QAT_HW Version 1.7 driver only.
./configure --enable-icp-thread-specific-usdm --enable-128k-slab
Note: See Limitations and Known Issues for multithreaded limitations, including performance with OpenSSL.
This step is not required if using the default USDM driver above. The Intel®
QAT OpenSSL* Engine comes with an example kernel space contiguous memory driver
that can be used to try out operation of the engine. It is considered to be an
example only and is not written to be a production quality driver.
The use of the qat_contig_mem driver can be enabled using the configure
option --enable-qat_hw_contig_mem
that tells the build that the Intel®
QAT OpenSSL* Engine should be compiled to use the qat_contig_mem component
instead of the USDM memory driver above.
Building and loading the qat_contig_mem driver assuming:
- The Intel® QAT OpenSSL* Engine was cloned to its own location at the
root of the drive:
/
.
To build/install the qat_contig_mem driver follow these steps:
cd /QAT_Engine/qat_contig_mem
make
make load
make test
The expected output from make test
should be something similar to the
following:
seg mapped to 0x7f9eedd6e000, virtualAddress in seg 0xffff880ac9c0c000,
length 64
Hello world!
# PASS Verify for QAT Contig Mem Test
QAT gen4 devices(4xxx) supports Shared Virtual Memory (SVM) that allows the use
of unpinned user space memory avoiding the memcpy of buffers to pinned contiguous memory.
The SVM support in the driver enables passing of virtual addresses to the QAT hardware for
processing acceleration requests, i.e. addresses are the same virtual addresses used in
the calling process supporting Zero-copy. This Support in the QAT Engine can be enabled
dynamically by setting SvmEnabled = 1
and ATEnabled = 1
in the QAT PF and VF device's
driver config file(s) along with other prerequistes mentioned below.
The Following parameter needs to be enabled in BIOS and is supported only in QAT gen4 devices.
- Support for Shared Virtual Memory with Intel IOMMU
- Enable VT-d
- Enable ATS
qat_sw Prerequisites
- Verify qat_sw components are installed as described in Software requirements
Install OpenSSL* (Note this step is not required if OpenSSL* is already installed)
This step is not required if building the Intel® QAT OpenSSL* Engine against system prebuilt OpenSSL* . When using the prebuild system OpenSSL library the engine library is installed in the system OpenSSL engines directory.
Clone OpenSSL* from Github* at the following location:
git clone https://github.com/openssl/openssl.git
It is recommended to checkout and build against the OpenSSL* git tag specified in the Software Requirements section.
Due to the nature of the Intel® QAT OpenSSL* Engine being a dynamic engine it can only be used with shared library builds of OpenSSL*.
Note: It is not recommended to install the accelerated version of OpenSSL* as
your default system library. If you do, you may find that acceleration is used
unexpectedly by other applications on the system resulting in
undesired/unsupported behaviour. The --prefix
can be used with the ./config
command to specify the location that make install
will copy files to. Please
see the OpenSSL* INSTALL file for full details on usage of the --prefix
option.
With OpenSSL* version 1.1.0 and on, binaries are installed in standard
directories by default, and the addition of runpath directories is not done
automatically. If you wish to install OpenSSL* in a non-standard location
(recommended), the runpath directories can be specified via the OpenSSL*
Configure command, which recognises the arguments -rpath
and -R
to support
user-added rpaths. For convenience, a Makefile variable LIBRPATH
has also
been added which is defined as the full path to a subdirectory of the
installation directory. The subdirectory is named lib
by default.
If you do not wish to use LIBRPATH
, the rpath can be specified directly.
The syntax for specifying a rpath is as follows:
./config [options] -Wl,-rpath,\${LIBRPATH}
The -rpath
can be replaced with -R
for brevity. If you do not wish
to use the built-in variable LIBRPATH, the syntax for specifying a rpath of
/usr/local/ssl/lib
for example would be:
./config [options] -Wl,-rpath,/usr/local/ssl/lib
Alternatively, you can specify the rpath by adding it to the environment
variable LD_LIBRARY_PATH
via the command:
export LD_LIBRARY_PATH=$LD_LIBRARY_PATH:`RPATH`
where RPATH
is the full path(s) to the shared libraries. This is not the
preferred method though.
`
The following example is assuming:
- The OpenSSL* source was cloned from Github* to its own location at the root
of the drive:
/
. - You want OpenSSL* to be installed to
/usr/local/ssl
.
An example build would be:
cd /openssl
./config --prefix=/usr/local/ssl -Wl,-rpath,\${LIBRPATH}
make depend (if recommended by the OpenSSL* build system)
make
make install
As the Intel® QAT OpenSSL* Engine will be built as a dynamic engine it is important to tell OpenSSL* where to find the dynamic engines at runtime. This is achieved by exporting the following environment variable (assuming the example paths above):
OpenSSL 1.1.1: export OPENSSL_ENGINES=/usr/local/ssl/lib/engines-1.1
OpenSSL 3.0: export OPENSSL_ENGINES=/usr/local/ssl/lib64/engines-3
Note: This variable will need to be present in the environment whenever the engine is used and not needed when provider is used.
Load/Initialize Engine using the OpenSSL* config file is located here
Further information on building OpenSSL* can be found in the INSTALL file distributed with the OpenSSL* source code or on the official OpenSSL* Wiki in the Compilation and Installation section: https://wiki.openssl.org/index.php/Compilation_and_Installation
Build the Intel® QuickAssist Technology OpenSSL* Engine
Clone the Github* repository containing the Intel® QAT OpenSSL* Engine:
git clone https://github.com/intel/QAT_Engine.git
When building it is possible to specify command line options that can be used to turn engine functionality on and off. The complete list of these options is available here.
The prerequisite to run autogen.sh is to have autotools (autoconf, automake, libtool and pkg-config) installed in the system.
cd /QAT_Engine
./autogen.sh
./autogen.sh will regenerate autoconf tools files.
Here are a few example builds that demonstrate how the Intel® QAT OpenSSL* Engine can be configured to use qat_hw and/or qat_sw.
Example 1: qat_hw target with OpenSSL\* built from source
The following example is assuming:
- The Intel® QAT OpenSSL* Engine was cloned to its own location at the root
of the drive:
/
. - The Intel® QAT Driver version 1.7 or 2.0 was unpacked within
/QAT
and using the USDM component. - OpenSSL* built from source is being used and installed to
/usr/local/ssl
.
To build and install the Intel® QAT OpenSSL* Engine:
cd /QAT_Engine
./configure \
--with-qat_hw_dir=/QAT \
--with-openssl_install_dir=/usr/local/ssl
make
make install
In the above example this will create the file qatengine.so
and copy it to
/usr/local/ssl/lib64/engines-3
.
For building QAT Engine against qatlib(intree driver) from source which is
installed to default location "/usr/local" use --with-qat_hw_dir=/usr/local
or provide the path that is used in the prefix to build qatlib.
If qatlib is installed via RPM (both library and development headers) then
-with-qat_hw_dir
is not needed as qatengine automatically picks qatlib
libraries and headers from the default location /usr/lib64
.
Example 2: qat_hw target with Prebuilt OpenSSL\*
The following example is assuming:
- The Intel® QAT OpenSSL* Engine was cloned to its own location at the root
of the drive:
/
. - The Intel® QAT Driver was unpacked within
/QAT
and using the USDM component. - Prebuilt OpenSSL* (both library and devel RPM packages) are installed in
the system and the OpenSSL* version is
3.0
or above.
To build and install the Intel® QAT OpenSSL* Engine:
cd /QAT_Engine
./configure --with-qat_hw_dir=/QAT
make
make install
In the above example this will create the file qatengine.so
and copy it to
the engines dir of the system which can be checked using
pkg-config --variable=enginesdir libcrypto
.
If qatlib is installed via RPM (both library and development headers) then
-with-qat_hw_dir
is not needed as qatengine automatically picks qatlib
libraries and headers from the default location /usr/lib64
.
Example 3: qat_hw + qat_sw target with Prebuilt OpenSSL\*
The following example is assuming:
- The Intel® QAT OpenSSL* Engine was cloned to its own location at the root
of the drive:
/
. - The Intel® QAT Driver was unpacked within
/QAT
and using the USDM component. - Intel® Multi-Buffer Crypto for IPsec Library was installed to the default path
- OpenSSL* built from source is being used and installed to
/usr/local/ssl
.
To build and install the Intel® QAT OpenSSL* Engine:
cd /QAT_Engine
./configure \
--with-qat_hw_dir=/QAT \
--enable-qat_sw \
--with-openssl_install_dir=/usr/local/ssl
make
make install
- In the above example this will create the file
qatengine.so
and copy it to/usr/local/ssl/lib64/engines-3
. - AES-GCM operations are handled by qat_sw
- Other cryptographic operations are handled by qat_hw
Example 4: qat_sw target with Prebuilt OpenSSL\*
The following example is assuming:
- The Intel® QAT OpenSSL* Engine was cloned to its own location at the root
of the drive:
/
. - The Intel® Crypto Multi-buffer library was installed to the default path (/usr/local).
- The Intel® Multi-Buffer crypto for IPsec Library was installed to its default path (/usr/). (Optional if QAT SW AES-GCM support is not needed).
- Prebuilt OpenSSL* from the system is used.
To build and install the Intel® QAT OpenSSL* Engine with QAT Software support:
cd /QAT_Engine
./configure --enable-qat_sw
make
make install
In the above example, --disable-qat_hw
needs to be provided if the system
has qatlib installed.
Note : --enable-qat_sw
checks crypto_mb and IPSec_MB libraries in its
respective default path (/usr/local/lib and /usr/lib) or in the path provided
in the config flag --with-qat_sw_crypto_mb_install_dir
(for crypto_mb) and
--with-qat_sw_ipsec_mb_install_dir
(for ipsec_mb). If any of the libraries
is not installed then their corresponding algorithm support is disabled
(crypto_mb library for PKE algorithms and IPSec_mb library for AES-GCM).
Example 5: Using `make depend` for building dependant libraries and build QAT Engine
This QAT Engine supports building and installing the dependant libraries automatically when
the make option make depend
is specified before make which clones the latest release of
dependant libraries (OpenSSL, QAT_HW(QAT1.7, QAT1.8 & QAT2.0 OOT Linux driver),
QAT_SW(ipp-crypto & ipsec_mb) based on the flags enabled in the QAT Engine build configure.
cd /QAT_Engine
git submodule update --init
./configure \
--with-qat_hw_dir=/QAT \ #For QAT_HW supported platforms
--enable-qat_sw \ #For QAT_SW supported platforms
--with-openssl_install_dir=/usr/local/ssl # OpenSSL install path
make depend
make
make install
In the above example this will clone and install QAT Engine(qat_hw + qat_sw)
along with their dependant libraries installed in the path specifed for QAT_HW
and default path for QAT_SW (/usr/local
for ipp-crypto & /usr
for ipsec_mb) with
qatengine.so library installed in the path /usr/local/ssl/lib64/engines-3
.
The dependant libaries are built and installed based on the QAT Engine build configure
flags provided for qat_hw, qat_sw or qat_hw + qat_sw target using OpenSSL3.0.
Please note make depend
target is not supported in FreeBSD OS, Virtualized environment,
BoringSSL, BabaSSL and qatlib dependency build. The Dependant library versions used are updated in
Software Requirements section
and OpenSSL version is latest of 3.0
make depend
is specified before make which clones the latest release of
dependant libraries (OpenSSL, QAT_HW(QAT1.7, QAT1.8 & QAT2.0 OOT Linux driver),
QAT_SW(ipp-crypto & ipsec_mb) based on the flags enabled in the QAT Engine build configure.cd /QAT_Engine
git submodule update --init
./configure \
--with-qat_hw_dir=/QAT \ #For QAT_HW supported platforms
--enable-qat_sw \ #For QAT_SW supported platforms
--with-openssl_install_dir=/usr/local/ssl # OpenSSL install path
make depend
make
make install
/usr/local
for ipp-crypto & /usr
for ipsec_mb) with
qatengine.so library installed in the path /usr/local/ssl/lib64/engines-3
.
The dependant libaries are built and installed based on the QAT Engine build configure
flags provided for qat_hw, qat_sw or qat_hw + qat_sw target using OpenSSL3.0.make depend
target is not supported in FreeBSD OS, Virtualized environment,
BoringSSL, BabaSSL and qatlib dependency build. The Dependant library versions used are updated in
Software Requirements section
and OpenSSL version is latest of 3.0Enable plock optimization in QAT Engine for Multithread applications
Progressive Lock (plock) optimization in QAT Engine provides an alternative to pthread's rwlock as in Haproxy. This plock is an alternative to read/write locks in the pthread library and optimizes read/write locking with a series of atomic operations and there will be no more syscalls in case of contention. The benefit of plock is that it saves lot of CPU and improves performance with higher number of threads for multithread applications. In case of Haproxy, this can directly enabled in the Haproxy build with addition build flag "USE_PTHREAD_EMULATION=1".
QAT Engine generates dynamic libraries and currently enables Plock by preloading.
- When compiling the qat engine, add the compilation option
--enable-qat_plock
, and thelibplock.so
will be generated. eg: ./configure --enable-qat_sw --enable-qat_plock --with-openssl_install_dir=${OPENSSL_INSTALL_DIR} - Set the environment variable ‘LD_PRELOAD’ to use the plock optimization.
eg: export LD_PRELOAD = ${OPENSSL_INSTALL_DIR}/lib/engine-1.1/libplock.so
Note: The
LD_PRELOAD
must be set before launching the multithread Application.
[For BoringSSL only] Build the Intel® QuickAssist Technology BoringSSL* Library
Please refer BoringSSL section for steps to build the Intel® QuickAssist Technology BoringSSL* library which supports RSA and ECDSA QAT Hardware and QAT Software Acceleration using BoringSSL.
Copy the Intel® QuickAssist Technology Driver config file(s)
This step is not required for qat_sw target. The Intel® QAT OpenSSL*
Engine includes example conf files to use with the Intel® QAT Driver.
The Intel® QAT OpenSSL* Engine will not function with the default
Intel® QAT Driver conf file because the default conf does not contain a
[SHIM]
section which the Intel® QAT OpenSSL* Engine requires by default.
The default section name in the QAT OpenSSL* Engine can be modified if required
by either using the engine ctrl command SET_CONFIGURATION_SECTION_NAME or by
setting the environment variable "QAT_SECTION_NAME".
The conf files are located at:
/path/to/qat_engine/qat_hw_config
The files are grouped by acceleration device(dh895xcc or c6xx or c3xxx or 200xx or c4xxx or 4xxx), please choose the files appropriate to your acceleration device only.
The files are also split into multi_process
and multi_thread
.
If your application runs one (or very few) processes, but has multiple threads
in each process, each accessing the acceleration device, then you should pick
the multi_thread
config files. An example of this is a webserver
that creates a new thread for each incoming connection.
If your application scales by creating new processes, then you should pick the
multi_process
config files. An example of this is an event driven
application that runs as a single thread in an event loop. In this type of
application it is usual for the application to create at least one new process
for each cpu core you want to utilize.
For event driven polling based application, change the parameter Cy$nIsPolled=1
to Cy$nIsPolled=2
for each instances($n) in the respective config file to use
event driven polling support. Event driven config files are only supported in Linux.
Once you have decided which config file you should use, or created your own you
should follow the procedure below to install it:
-
Stop the acceleration driver as described in the Section 3.4 Starting/Stopping the Acceleration software from the Getting Started Guide available in Intel® QuickAssist Technology Driver
-
Copy the appropriate
.conf
file to/etc
for n number of QAT devices -
Start the acceleration driver as described in the Section 3.4 Starting/Stopping the Acceleration software from the Getting Started Guide available in Intel® QuickAssist Technology Driver
Test the Intel® QuickAssist Technology OpenSSL* Engine
Run this command to verify the Intel® QAT OpenSSL* Engine is loaded correctly: This should not be used to determine QAT Engine capabilities as it will not display all the algorithms that are supported in QAT Engine.
cd /path/to/openssl_install/bin
./openssl engine -t -c -v qatengine
qat_hw target output will be:
(qatengine) Reference implementation of QAT crypto engine(qat_hw) <qatengine version>
[RSA, DSA, DH, AES-128-CBC-HMAC-SHA1, AES-128-CBC-HMAC-SHA256,
AES-256-CBC-HMAC-SHA1, AES-256-CBC-HMAC-SHA256, TLS1-PRF, HKDF, X25519, X448]
[ available ]
ENABLE_EXTERNAL_POLLING, POLL, SET_INSTANCE_FOR_THREAD,
GET_NUM_OP_RETRIES, SET_MAX_RETRY_COUNT, SET_INTERNAL_POLL_INTERVAL,
GET_EXTERNAL_POLLING_FD, ENABLE_EVENT_DRIVEN_POLLING_MODE,
GET_NUM_CRYPTO_INSTANCES, DISABLE_EVENT_DRIVEN_POLLING_MODE,
SET_EPOLL_TIMEOUT, SET_CRYPTO_SMALL_PACKET_OFFLOAD_THRESHOLD,
ENABLE_INLINE_POLLING, ENABLE_HEURISTIC_POLLING,
GET_NUM_REQUESTS_IN_FLIGHT, INIT_ENGINE, SET_CONFIGURATION_SECTION_NAME,
ENABLE_SW_FALLBACK, HEARTBEAT_POLL, DISABLE_QAT_OFFLOAD
qat_sw target output will be:
(qatengine) Reference implementation of QAT crypto engine(qat_sw) <qatengine version>
[RSA, id-aes128-GCM, id-aes192-GCM, id-aes256-GCM, X25519]
[ available ]
ENABLE_EXTERNAL_POLLING, POLL, ENABLE_HEURISTIC_POLLING,
GET_NUM_REQUESTS_IN_FLIGHT, INIT_ENGINE
Detailed information about the engine specific messages is available here.
Also ./openssl engine -t -c -vvvv qatengine
gives brief description about each ctrl command.
Testing the Intel® QuickAssist Technology OpenSSL* Engine using OpenSSL* speed utility
cd /path/to/openssl_install/bin
qat_hw
* RSA 2K
* Asynchronous
./openssl speed -engine qatengine -elapsed -async_jobs 72 rsa2048
* Synchronous
./openssl speed -engine qatengine -elapsed rsa2048
* OpenSSL Software
./openssl speed -elapsed rsa2048
* ECDH Compute Key
* Asynchronous
./openssl speed -engine qatengine -elapsed -async_jobs 36 ecdh
* Synchronous
./openssl speed -engine qatengine -elapsed ecdh
* OpenSSL Software
./openssl speed -elapsed ecdh
* Chained Cipher: aes-128-cbc-hmac-sha1
* Asynchronous
./openssl speed -engine qatengine -elapsed -async_jobs 128 -multi 2 -evp aes-128-cbc-hmac-sha1
* Synchronous
./openssl speed -engine qatengine -elapsed -multi 2 -evp aes-128-cbc-hmac-sha1
* OpenSSL Software
./openssl speed -elapsed -multi 2 -evp aes-128-cbc-hmac-sha1
qat_sw (Intel(R) Crypto Multi-buffer library)
* RSA 2K
./openssl speed -engine qatengine -elapsed -async_jobs 8 rsa2048
* ECDH X25519
./openssl speed -engine qatengine -elapsed -async_jobs 8 ecdhx25519
* ECDH P-256
./openssl speed -engine qatengine -elapsed -async_jobs 8 ecdhp256
* ECDSA P-256
./openssl speed -engine qatengine -elapsed -async_jobs 8 ecdsap256
* ECDH P-384
./openssl speed -engine qatengine -elapsed -async_jobs 8 ecdhp384
* ECDSA P-384
./openssl speed -engine qatengine -elapsed -async_jobs 8 ecdsap384
qat_sw (Intel(R) Multi-Buffer Crypto for IPsec)
* AES-128-GCM
./openssl speed -engine qatengine -elapsed -evp aes-128-gcm
* AES-192-GCM
./openssl speed -engine qatengine -elapsed -evp aes-192-gcm
* AES-256-GCM
./openssl speed -engine qatengine -elapsed -evp aes-256-gcm
Testing the Intel® QuickAssist Technology OpenSSL* Engine using testapp utility
cd /path/to/qat_engine
make test
./testapp.sh QAT_HW (For testing algorithms supported by QAT_HW)
./testapp.sh QAT_SW (For testing algorithms supported by QAT_SW)
The testapp.sh
script will run the corresponding functional tests supported
by QAT_HW and QAT_SW. Please note that the QAT Engine should be built with
that support for the tests.
Additional information for testapp tests available with the help option
./testapp -help
Troubleshooting information is available here.
Links to additional content is available here.
Licensing information is available here.
Legal information is available here.