15. DPAA2 Poll Mode Driver
The DPAA2 NIC PMD (librte_net_dpaa2) provides poll mode driver support for the inbuilt NIC found in the NXP DPAA2 SoC family.
More information can be found at NXP Official Website.
15.1. NXP DPAA2 (Data Path Acceleration Architecture Gen2)
This section provides an overview of the NXP DPAA2 architecture and how it is integrated into the DPDK.
- DPAA2 overview
- Overview of DPAA2 objects
- DPAA2 driver architecture overview
15.1.1. DPAA2 Overview
Reference: FSL MC BUS in Linux Kernel.
DPAA2 is a hardware architecture designed for high-speed network packet processing. DPAA2 consists of sophisticated mechanisms for processing Ethernet packets, queue management, buffer management, autonomous L2 switching, virtual Ethernet bridging, and accelerator (e.g. crypto) sharing.
A DPAA2 hardware component called the Management Complex (or MC) manages the DPAA2 hardware resources. The MC provides an object-based abstraction for software drivers to use the DPAA2 hardware.
The MC uses DPAA2 hardware resources such as queues, buffer pools, and network ports to create functional objects/devices such as network interfaces, an L2 switch, or accelerator instances.
The MC provides memory-mapped I/O command interfaces (MC portals) which DPAA2 software drivers use to operate on DPAA2 objects:
The diagram below shows an overview of the DPAA2 resource management architecture:
+--------------------------------------+ | OS | | DPAA2 drivers | | | | +-----------------------------|--------+ | | (create,discover,connect | config,use,destroy) | DPAA2 | +------------------------| mc portal |-+ | | | | +- - - - - - - - - - - - -V- - -+ | | | | | | | Management Complex (MC) | | | | | | | +- - - - - - - - - - - - - - - -+ | | | | Hardware Hardware | | Resources Objects | | --------- ------- | | -queues -DPRC | | -buffer pools -DPMCP | | -Eth MACs/ports -DPIO | | -network interface -DPNI | | profiles -DPMAC | | -queue portals -DPBP | | -MC portals ... | | ... | | | +--------------------------------------+
The MC mediates operations such as create, discover, connect, configuration, and destroy. Fast-path operations on data, such as packet transmit/receive, are not mediated by the MC and are done directly using memory mapped regions in DPIO objects.
15.1.2. Overview of DPAA2 Objects
The section provides a brief overview of some key DPAA2 objects. A simple scenario is described illustrating the objects involved in creating a network interfaces.
DPRC (Datapath Resource Container)
A DPRC is a container object that holds all the other types of DPAA2 objects. In the example diagram below there are 8 objects of 5 types (DPMCP, DPIO, DPBP, DPNI, and DPMAC) in the container.
+---------------------------------------------------------+ | DPRC | | | | +-------+ +-------+ +-------+ +-------+ +-------+ | | | DPMCP | | DPIO | | DPBP | | DPNI | | DPMAC | | | +-------+ +-------+ +-------+ +---+---+ +---+---+ | | | DPMCP | | DPIO | | | +-------+ +-------+ | | | DPMCP | | | +-------+ | | | +---------------------------------------------------------+
From the point of view of an OS, a DPRC behaves similar to a plug and play bus, like PCI. DPRC commands can be used to enumerate the contents of the DPRC, discover the hardware objects present (including mappable regions and interrupts).
DPRC.1 (bus) | +--+--------+-------+-------+-------+ | | | | | DPMCP.1 DPIO.1 DPBP.1 DPNI.1 DPMAC.1 DPMCP.2 DPIO.2 DPMCP.3
Hardware objects can be created and destroyed dynamically, providing the ability to hot plug/unplug objects in and out of the DPRC.
A DPRC has a mappable MMIO region (an MC portal) that can be used to send MC commands. It has an interrupt for status events (like hotplug).
All objects in a container share the same hardware “isolation context”. This means that with respect to an IOMMU the isolation granularity is at the DPRC (container) level, not at the individual object level.
DPRCs can be defined statically and populated with objects via a config file passed to the MC when firmware starts it. There is also a Linux user space tool called “restool” that can be used to create/destroy containers and objects dynamically.
15.1.3. DPAA2 Objects for an Ethernet Network Interface
A typical Ethernet NIC is monolithic– the NIC device contains TX/RX queuing mechanisms, configuration mechanisms, buffer management, physical ports, and interrupts. DPAA2 uses a more granular approach utilizing multiple hardware objects. Each object provides specialized functions. Groups of these objects are used by software to provide Ethernet network interface functionality. This approach provides efficient use of finite hardware resources, flexibility, and performance advantages.
The diagram below shows the objects needed for a simple network interface configuration on a system with 2 CPUs.
+---+---+ +---+---+ CPU0 CPU1 +---+---+ +---+---+ | | +---+---+ +---+---+ DPIO DPIO +---+---+ +---+---+ \ / \ / \ / +---+---+ DPNI --- DPBP,DPMCP +---+---+ | | +---+---+ DPMAC +---+---+ | port/PHY
Below the objects are described. For each object a brief description is provided along with a summary of the kinds of operations the object supports and a summary of key resources of the object (MMIO regions and IRQs).
DPMAC (Datapath Ethernet MAC): represents an Ethernet MAC, a hardware device that connects to an Ethernet PHY and allows physical transmission and reception of Ethernet frames.
- MMIO regions: none
- IRQs: DPNI link change
- commands: set link up/down, link config, get stats, IRQ config, enable, reset
DPNI (Datapath Network Interface): contains TX/RX queues, network interface configuration, and RX buffer pool configuration mechanisms. The TX/RX queues are in memory and are identified by queue number.
- MMIO regions: none
- IRQs: link state
- commands: port config, offload config, queue config, parse/classify config, IRQ config, enable, reset
DPIO (Datapath I/O): provides interfaces to enqueue and dequeue packets and do hardware buffer pool management operations. The DPAA2 architecture separates the mechanism to access queues (the DPIO object) from the queues themselves. The DPIO provides an MMIO interface to enqueue/dequeue packets. To enqueue something a descriptor is written to the DPIO MMIO region, which includes the target queue number. There will typically be one DPIO assigned to each CPU. This allows all CPUs to simultaneously perform enqueue/dequeued operations. DPIOs are expected to be shared by different DPAA2 drivers.
- MMIO regions: queue operations, buffer management
- IRQs: data availability, congestion notification, buffer pool depletion
- commands: IRQ config, enable, reset
DPBP (Datapath Buffer Pool): represents a hardware buffer pool.
- MMIO regions: none
- IRQs: none
- commands: enable, reset
DPMCP (Datapath MC Portal): provides an MC command portal. Used by drivers to send commands to the MC to manage objects.
- MMIO regions: MC command portal
- IRQs: command completion
- commands: IRQ config, enable, reset
15.1.4. Object Connections
Some objects have explicit relationships that must be configured:
- DPNI <–> DPMAC
- DPNI <–> DPNI
- DPNI <–> L2-switch-port
A DPNI must be connected to something such as a DPMAC, another DPNI, or L2 switch port. The DPNI connection is made via a DPRC command.
+-------+ +-------+ | DPNI | | DPMAC | +---+---+ +---+---+ | | +==========+
- DPNI <–> DPBP
A network interface requires a ‘buffer pool’ (DPBP object) which provides a list of pointers to memory where received Ethernet data is to be copied. The Ethernet driver configures the DPBPs associated with the network interface.
All interrupts generated by DPAA2 objects are message interrupts. At the hardware level message interrupts generated by devices will normally have 3 components– 1) a non-spoofable ‘device-id’ expressed on the hardware bus, 2) an address, 3) a data value.
In the case of DPAA2 devices/objects, all objects in the same container/DPRC share the same ‘device-id’. For ARM-based SoC this is the same as the stream ID.
15.2. DPAA2 DPDK - Poll Mode Driver Overview
This section provides an overview of the drivers for DPAA2– 1) the bus driver and associated “DPAA2 infrastructure” drivers and 2) functional object drivers (such as Ethernet).
As described previously, a DPRC is a container that holds the other types of DPAA2 objects. It is functionally similar to a plug-and-play bus controller.
Each object in the DPRC is a Linux “device” and is bound to a driver. The diagram below shows the dpaa2 drivers involved in a networking scenario and the objects bound to each driver. A brief description of each driver follows.
+------------+ | DPDK DPAA2 | | PMD | +------------+ +------------+ | Ethernet |.......| Mempool | . . . . . . . . . | (DPNI) | | (DPBP) | . +---+---+----+ +-----+------+ . ^ | . . | |<enqueue, . . | | dequeue> . . | | . . +---+---V----+ . . . . . . . . . . . .| DPIO driver| . . . | (DPIO) | . . . +-----+------+ . . . | QBMAN | . . . | Driver | . +----+------+-------+ +-----+----- | . | dpaa2 bus | | . | VFIO fslmc-bus |....................|..................... | | | | /bus/fslmc | | +-------------------+ | | ========================== HARDWARE =====|======================= DPIO | DPNI---DPBP | DPMAC | PHY =========================================|========================
A brief description of each driver is provided below.
15.2.1. DPAA2 bus driver
The DPAA2 bus driver is a rte_bus driver which scans the fsl-mc bus. Key functions include:
- Reading the container and setting up vfio group
- Scanning and parsing the various MC objects and adding them to their respective device list.
Additionally, it also provides the object driver for generic MC objects.
15.2.2. DPIO driver
The DPIO driver is bound to DPIO objects and provides services that allow other drivers such as the Ethernet driver to enqueue and dequeue data for their respective objects. Key services include:
- Data availability notifications
- Hardware queuing operations (enqueue and dequeue of data)
- Hardware buffer pool management
To transmit a packet the Ethernet driver puts data on a queue and invokes a DPIO API. For receive, the Ethernet driver registers a data availability notification callback. To dequeue a packet a DPIO API is used.
There is typically one DPIO object per physical CPU for optimum performance, allowing different CPUs to simultaneously enqueue and dequeue data.
The DPIO driver operates on behalf of all DPAA2 drivers active – Ethernet, crypto, compression, etc.
15.2.3. DPBP based Mempool driver
The DPBP driver is bound to a DPBP objects and provides services to create a hardware offloaded packet buffer mempool.
15.2.4. DPAA2 NIC Driver
The Ethernet driver is bound to a DPNI and implements the kernel interfaces needed to connect the DPAA2 network interface to the network stack.
Each DPNI corresponds to a DPDK network interface.
Features of the DPAA2 PMD are:
- Multiple queues for TX and RX
- Receive Side Scaling (RSS)
- MAC/VLAN filtering
- Packet type information
- Checksum offload
- Promiscuous mode
- Multicast mode
- Port hardware statistics
- Jumbo frames
- Link flow control
- Scattered and gather for TX and RX
- Traffic Management API
15.3. Supported DPAA2 SoCs
See NXP QorIQ DPAA2 Board Support Package for setup information
- Follow the DPDK Getting Started Guide for Linux to setup the basic DPDK environment.
Some part of fslmc bus code (mc flib - object library) routines are dual licensed (BSD & GPLv2), however they are used as BSD in DPDK in userspace.
15.5. Driver compilation and testing
Refer to the document compiling and testing a PMD for a NIC for details.
Follow instructions available in the document compiling and testing a PMD for a NIC to run testpmd.
./dpdk-testpmd -c 0xff -n 1 -- -i --portmask=0x3 --nb-cores=1 --no-flush-rx ..... EAL: Registered [pci] bus. EAL: Registered [fslmc] bus. EAL: Detected 8 lcore(s) EAL: Probing VFIO support... EAL: VFIO support initialized ..... PMD: DPAA2: Processing Container = dprc.2 EAL: fslmc: DPRC contains = 51 devices EAL: fslmc: Bus scan completed ..... Configuring Port 0 (socket 0) Port 0: 00:00:00:00:00:01 Configuring Port 1 (socket 0) Port 1: 00:00:00:00:00:02 ..... Checking link statuses... Port 0 Link Up - speed 10000 Mbps - full-duplex Port 1 Link Up - speed 10000 Mbps - full-duplex Done testpmd>
- Use dev arg option
drv_loopback=1to loopback packets at driver level. Any packet received will be reflected back by the driver on same port. e.g.
- Use dev arg option
drv_no_prefetch=1to disable prefetching of the packet pull command which is issued in the previous cycle. e.g.
- Use dev arg option
drv_tx_conf=1to enable TX confirmation mode. In this mode tx conf queues need to be polled to free the buffers. e.g.
- Use dev arg option
drv_error_queue=1to enable Packets in Error queue. DPAA2 hardware drops the error packet in hardware. This option enables the hardware to not drop the error packet and let the driver dump the error packets, so that user can check what is wrong with those packets. e.g.
15.6. Enabling logs
For enabling logging for DPAA2 PMD, following log-level prefix can be used:
<dpdk app> <EAL args> --log-level=bus.fslmc:<level> -- ...
bus.fslmc as log matching criteria, all FSLMC bus logs can be enabled
which are lower than logging
Or<dpdk app> <EAL args> --log-level=pmd.net.dpaa2:<level> -- ...
pmd.net.dpaa2 as log matching criteria, all PMD logs can be enabled
which are lower than logging
15.7. Allowing & Blocking
For blocking a DPAA2 device, following commands can be used.
<dpdk app> <EAL args> -b "fslmc:dpni.x" -- ...
Where x is the device object id as configured in resource container.
15.8. Running secondary debug app without blocklist
dpaa2 hardware imposes limits on some H/W access devices like Management Control Port and H/W portal. This causes issue in their shared usages in case of multi-process applications. It can overcome by using allowlist/blocklist in primary and secondary applications.
In order to ease usage of standard debugging apps like dpdk-procinfo, dpaa2 driver reserves extra Management Control Port and H/W portal which can be used by debug application to debug any existing application without blocking these devices in primary process.
15.9.1. Platform Requirement
DPAA2 drivers for DPDK can only work on NXP SoCs as listed in the
Supported DPAA2 SoCs.
15.9.2. Maximum packet length
The DPAA2 SoC family support a maximum of a 10240 jumbo frame. The value
is fixed and cannot be changed. So, even when the
struct rte_eth_conf is set to a value lower than 10240, frames
up to 10240 bytes can still reach the host interface.
15.9.3. Other Limitations
- RSS hash key cannot be modified.
- RSS RETA cannot be configured.
15.10. Traffic Management API
DPAA2 PMD supports generic DPDK Traffic Management API which allows to configure the following features:
- Hierarchical scheduling
- Traffic shaping
Internally TM is represented by a hierarchy (tree) of nodes. Node which has a parent is called a leaf whereas node without parent is called a non-leaf (root).
Nodes hold following types of settings:
- for egress scheduler configuration: weight
- for egress rate limiter: private shaper
Hierarchy is always constructed from the top, i.e first a root node is added then some number of leaf nodes. Number of leaf nodes cannot exceed number of configured tx queues.
After hierarchy is complete it can be committed.
For an additional description please refer to DPDK Traffic Management API.
15.10.1. Supported Features
The following capabilities are supported:
Level0 (root node) and Level1 are supported.
1 private shaper at root node (port level) is supported.
8 TX queues per port supported (1 channel per port)
Both SP and WFQ scheduling mechanisms are supported on all 8 queues.
- Congestion notification is supported. It means if there is congestion on
the network, DPDK driver will not enqueue any packet (no taildrop or WRED)
User can also check node, level capabilities using testpmd commands.
15.10.2. Usage example
For a detailed usage description please refer to “Traffic Management” section in DPDK Testpmd Runtime Functions.
Run testpmd as follows:
./dpdk-testpmd -c 0xf -n 1 -- -i --portmask 0x3 --nb-cores=1 --txq=4 --rxq=4
Stop all ports:
testpmd> port stop all
Add shaper profile:
One port level shaper and strict priority on all 4 queues of port 0:
add port tm node shaper profile 0 1 104857600 64 100 0 0 add port tm nonleaf node 0 8 -1 0 1 0 1 1 1 0 add port tm leaf node 0 0 8 0 1 1 -1 0 0 0 0 add port tm leaf node 0 1 8 1 1 1 -1 0 0 0 0 add port tm leaf node 0 2 8 2 1 1 -1 0 0 0 0 add port tm leaf node 0 3 8 3 1 1 -1 0 0 0 0 port tm hierarchy commit 0 no or
One port level shaper and WFQ on all 4 queues of port 0:
add port tm node shaper profile 0 1 104857600 64 100 0 0 add port tm nonleaf node 0 8 -1 0 1 0 1 1 1 0 add port tm leaf node 0 0 8 0 200 1 -1 0 0 0 0 add port tm leaf node 0 1 8 0 300 1 -1 0 0 0 0 add port tm leaf node 0 2 8 0 400 1 -1 0 0 0 0 add port tm leaf node 0 3 8 0 500 1 -1 0 0 0 0 port tm hierarchy commit 0 no
Create flows as per the source IP addresses:
flow create 1 group 0 priority 1 ingress pattern ipv4 src is \ 10.10.10.1 / end actions queue index 0 / end flow create 1 group 0 priority 2 ingress pattern ipv4 src is \ 10.10.10.2 / end actions queue index 1 / end flow create 1 group 0 priority 3 ingress pattern ipv4 src is \ 10.10.10.3 / end actions queue index 2 / end flow create 1 group 0 priority 4 ingress pattern ipv4 src is \ 10.10.10.4 / end actions queue index 3 / end
Start all ports
testpmd> port start all
Inject the traffic on port1 as per the configured flows, you will see shaped and scheduled forwarded traffic on port0