11. Intel(R) QuickAssist (QAT) Crypto Poll Mode Driver

The QAT PMD provides poll mode crypto driver support for the following hardware accelerator devices:

  • Intel QuickAssist Technology DH895xCC
  • Intel QuickAssist Technology C62x
  • Intel QuickAssist Technology C3xxx
  • Intel QuickAssist Technology D15xx

11.1. Features

The QAT PMD has support for:

Cipher algorithms:

  • RTE_CRYPTO_CIPHER_3DES_CBC
  • RTE_CRYPTO_CIPHER_3DES_CTR
  • RTE_CRYPTO_CIPHER_AES128_CBC
  • RTE_CRYPTO_CIPHER_AES192_CBC
  • RTE_CRYPTO_CIPHER_AES256_CBC
  • RTE_CRYPTO_CIPHER_AES128_CTR
  • RTE_CRYPTO_CIPHER_AES192_CTR
  • RTE_CRYPTO_CIPHER_AES256_CTR
  • RTE_CRYPTO_CIPHER_SNOW3G_UEA2
  • RTE_CRYPTO_CIPHER_NULL
  • RTE_CRYPTO_CIPHER_KASUMI_F8
  • RTE_CRYPTO_CIPHER_DES_CBC
  • RTE_CRYPTO_CIPHER_AES_DOCSISBPI
  • RTE_CRYPTO_CIPHER_DES_DOCSISBPI
  • RTE_CRYPTO_CIPHER_ZUC_EEA3

Hash algorithms:

  • RTE_CRYPTO_AUTH_SHA1_HMAC
  • RTE_CRYPTO_AUTH_SHA224_HMAC
  • RTE_CRYPTO_AUTH_SHA256_HMAC
  • RTE_CRYPTO_AUTH_SHA384_HMAC
  • RTE_CRYPTO_AUTH_SHA512_HMAC
  • RTE_CRYPTO_AUTH_AES_XCBC_MAC
  • RTE_CRYPTO_AUTH_SNOW3G_UIA2
  • RTE_CRYPTO_AUTH_MD5_HMAC
  • RTE_CRYPTO_AUTH_NULL
  • RTE_CRYPTO_AUTH_KASUMI_F9
  • RTE_CRYPTO_AUTH_AES_GMAC
  • RTE_CRYPTO_AUTH_ZUC_EIA3

Supported AEAD algorithms: * RTE_CRYPTO_AEAD_AES_GCM

11.2. Limitations

  • Only supports the session-oriented API implementation (session-less APIs are not supported).
  • SNOW 3G (UEA2), KASUMI (F8) and ZUC (EEA3) supported only if cipher length and offset fields are byte-multiple.
  • SNOW 3G (UIA2) and ZUC (EIA3) supported only if hash length and offset fields are byte-multiple.
  • No BSD support as BSD QAT kernel driver not available.
  • ZUC EEA3/EIA3 is not supported by dh895xcc devices
  • Maximum additional authenticated data (AAD) for GCM is 240 bytes long.

11.3. Installation

To enable QAT in DPDK, follow the instructions for modifying the compile-time configuration file as described here.

Quick instructions are as follows:

cd to the top-level DPDK directory
make config T=x86_64-native-linuxapp-gcc
sed -i 's,\(CONFIG_RTE_LIBRTE_PMD_QAT\)=n,\1=y,' build/.config
make

To use the DPDK QAT PMD an SRIOV-enabled QAT kernel driver is required. The VF devices exposed by this driver will be used by the QAT PMD. The devices and available kernel drivers and device ids are :

Table 11.1 QAT device generations, devices and drivers
Gen Device Driver Kernel Module Pci Driver PF Did #PFs Vf Did VFs/PF
1 DH895xCC 01.org icp_qa_al n/a 435 1 443 32
1 DH895xCC 4.4+ qat_dh895xcc dh895xcc 435 1 443 32
2 C62x 4.5+ qat_c62x c6xx 37c8 3 37c9 16
2 C3xxx 4.5+ qat_c3xxx c3xxx 19e2 1 19e3 16
2 D15xx p qat_d15xx d15xx 6f54 1 6f55 16

The Driver column indicates either the Linux kernel version in which support for this device was introduced or a driver available on Intel’s 01.org website. There are both linux and 01.org kernel drivers available for some devices. p = release pending.

If you are running on a kernel which includes a driver for your device, see Installation using kernel.org driver below. Otherwise see Installation using 01.org QAT driver.

11.4. Installation using kernel.org driver

The examples below are based on the C62x device, if you have a different device use the corresponding values in the above table.

In BIOS ensure that SRIOV is enabled and either:

  • Disable VT-d or
  • Enable VT-d and set "intel_iommu=on iommu=pt" in the grub file.

Check that the QAT driver is loaded on your system, by executing:

lsmod | grep qa

You should see the kernel module for your device listed, e.g.:

qat_c62x               5626  0
intel_qat              82336  1 qat_c62x

Next, you need to expose the Virtual Functions (VFs) using the sysfs file system.

First find the BDFs (Bus-Device-Function) of the physical functions (PFs) of your device, e.g.:

lspci -d : 37c8

You should see output similar to:

1a:00.0 Co-processor: Intel Corporation Device 37c8
3d:00.0 Co-processor: Intel Corporation Device 37c8
3f:00.0 Co-processor: Intel Corporation Device 37c8

Enable the VFs for each PF by echoing the number of VFs per PF to the pci driver:

echo 16 > /sys/bus/pci/drivers/c6xx/0000:1a:00.0/sriov_numvfs
echo 16 > /sys/bus/pci/drivers/c6xx/0000:3d:00.0/sriov_numvfs
echo 16 > /sys/bus/pci/drivers/c6xx/0000:3f:00.0/sriov_numvfs

Check that the VFs are available for use. For example lspci -d:37c9 should list 48 VF devices available for a C62x device.

To complete the installation follow the instructions in Binding the available VFs to the DPDK UIO driver.

Note

If the QAT kernel modules are not loaded and you see an error like Failed to load MMP firmware qat_895xcc_mmp.bin in kernel logs, this may be as a result of not using a distribution, but just updating the kernel directly.

Download firmware from the kernel firmware repo.

Copy qat binaries to /lib/firmware:

cp qat_895xcc.bin /lib/firmware
cp qat_895xcc_mmp.bin /lib/firmware

Change to your linux source root directory and start the qat kernel modules:

insmod ./drivers/crypto/qat/qat_common/intel_qat.ko
insmod ./drivers/crypto/qat/qat_dh895xcc/qat_dh895xcc.ko

Note

If you see the following warning in /var/log/messages it can be ignored: IOMMU should be enabled for SR-IOV to work correctly.

11.5. Installation using 01.org QAT driver

Download the latest QuickAssist Technology Driver from 01.org. Consult the Getting Started Guide at the same URL for further information.

The steps below assume you are:

  • Building on a platform with one DH895xCC device.
  • Using package qatmux.l.2.3.0-34.tgz.
  • On Fedora21 kernel 3.17.4-301.fc21.x86_64.

In the BIOS ensure that SRIOV is enabled and VT-d is disabled.

Uninstall any existing QAT driver, for example by running:

  • ./installer.sh uninstall in the directory where originally installed.
  • or rmmod qat_dh895xcc; rmmod intel_qat.

Build and install the SRIOV-enabled QAT driver:

mkdir /QAT
cd /QAT

# Copy qatmux.l.2.3.0-34.tgz to this location
tar zxof qatmux.l.2.3.0-34.tgz

export ICP_WITHOUT_IOMMU=1
./installer.sh install QAT1.6 host

You can use cat /proc/icp_dh895xcc_dev0/version to confirm the driver is correctly installed. You can use lspci -d:443 to confirm the of the 32 VF devices available per DH895xCC device.

To complete the installation - follow instructions in Binding the available VFs to the DPDK UIO driver.

Note

If using a later kernel and the build fails with an error relating to strict_stroul not being available apply the following patch:

/QAT/QAT1.6/quickassist/utilities/downloader/Target_CoreLibs/uclo/include/linux/uclo_platform.h
+ #if LINUX_VERSION_CODE >= KERNEL_VERSION(3,18,5)
+ #define STR_TO_64(str, base, num, endPtr) {endPtr=NULL; if (kstrtoul((str), (base), (num))) printk("Error strtoull convert %s\n", str); }
+ #else
#if LINUX_VERSION_CODE >= KERNEL_VERSION(2,6,38)
#define STR_TO_64(str, base, num, endPtr) {endPtr=NULL; if (strict_strtoull((str), (base), (num))) printk("Error strtoull convert %s\n", str); }
#else
#if LINUX_VERSION_CODE >= KERNEL_VERSION(2,6,25)
#define STR_TO_64(str, base, num, endPtr) {endPtr=NULL; strict_strtoll((str), (base), (num));}
#else
#define STR_TO_64(str, base, num, endPtr)                                 \
     do {                                                               \
           if (str[0] == '-')                                           \
           {                                                            \
                *(num) = -(simple_strtoull((str+1), &(endPtr), (base))); \
           }else {                                                      \
                *(num) = simple_strtoull((str), &(endPtr), (base));      \
           }                                                            \
     } while(0)
+ #endif
#endif
#endif

Note

If the build fails due to missing header files you may need to do following:

sudo yum install zlib-devel
sudo yum install openssl-devel

Note

If the build or install fails due to mismatching kernel sources you may need to do the following:

sudo yum install kernel-headers-`uname -r`
sudo yum install kernel-src-`uname -r`
sudo yum install kernel-devel-`uname -r`

11.6. Binding the available VFs to the DPDK UIO driver

Unbind the VFs from the stock driver so they can be bound to the uio driver.

11.6.1. For an Intel(R) QuickAssist Technology DH895xCC device

The unbind command below assumes BDFs of 03:01.00-03:04.07, if your VFs are different adjust the unbind command below:

for device in $(seq 1 4); do \
    for fn in $(seq 0 7); do \
        echo -n 0000:03:0${device}.${fn} > \
        /sys/bus/pci/devices/0000\:03\:0${device}.${fn}/driver/unbind; \
    done; \
done

11.6.2. For an Intel(R) QuickAssist Technology C62x device

The unbind command below assumes BDFs of 1a:01.00-1a:02.07, 3d:01.00-3d:02.07 and 3f:01.00-3f:02.07, if your VFs are different adjust the unbind command below:

for device in $(seq 1 2); do \
    for fn in $(seq 0 7); do \
        echo -n 0000:1a:0${device}.${fn} > \
        /sys/bus/pci/devices/0000\:1a\:0${device}.${fn}/driver/unbind; \

        echo -n 0000:3d:0${device}.${fn} > \
        /sys/bus/pci/devices/0000\:3d\:0${device}.${fn}/driver/unbind; \

        echo -n 0000:3f:0${device}.${fn} > \
        /sys/bus/pci/devices/0000\:3f\:0${device}.${fn}/driver/unbind; \
    done; \
done

11.6.3. For Intel(R) QuickAssist Technology C3xxx or D15xx device

The unbind command below assumes BDFs of 01:01.00-01:02.07, if your VFs are different adjust the unbind command below:

for device in $(seq 1 2); do \
    for fn in $(seq 0 7); do \
        echo -n 0000:01:0${device}.${fn} > \
        /sys/bus/pci/devices/0000\:01\:0${device}.${fn}/driver/unbind; \
    done; \
done

11.6.4. Bind to the DPDK uio driver

Install the DPDK igb_uio driver, bind the VF PCI Device id to it and use lspci to confirm the VF devices are now in use by igb_uio kernel driver, e.g. for the C62x device:

cd to the top-level DPDK directory
modprobe uio
insmod ./build/kmod/igb_uio.ko
echo "8086 37c9" > /sys/bus/pci/drivers/igb_uio/new_id
lspci -vvd:37c9

Another way to bind the VFs to the DPDK UIO driver is by using the dpdk-devbind.py script:

cd to the top-level DPDK directory
./usertools/dpdk-devbind.py -b igb_uio 0000:03:01.1

11.7. Extra notes on KASUMI F9

When using KASUMI F9 authentication algorithm, the input buffer must be constructed according to the 3GPP KASUMI specifications (section 4.4, page 13): http://cryptome.org/3gpp/35201-900.pdf. Input buffer has to have COUNT (4 bytes), FRESH (4 bytes), MESSAGE and DIRECTION (1 bit) concatenated. After the DIRECTION bit, a single ‘1’ bit is appended, followed by between 0 and 7 ‘0’ bits, so that the total length of the buffer is multiple of 8 bits. Note that the actual message can be any length, specified in bits.

Once this buffer is passed this way, when creating the crypto operation, length of data to authenticate (op.sym.auth.data.length) must be the length of all the items described above, including the padding at the end. Also, offset of data to authenticate (op.sym.auth.data.offset) must be such that points at the start of the COUNT bytes.