This includes removing use of lib/bdev/<module_name> which confused Doxygen into thinking it was an xml/html tag. Signed-off-by: Jim Harris <james.r.harris@intel.com> Change-Id: Iebfe84c1cbc59cd7a62e88dafbe1725d7c2a49da Reviewed-on: https://review.gerrithub.io/415851 Reviewed-by: Ben Walker <benjamin.walker@intel.com> Tested-by: SPDK Automated Test System <sys_sgsw@intel.com>
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iSCSI Target
iSCSI Target Getting Started Guide
The Storage Performance Development Kit iSCSI target application is named iscsi_tgt
.
This following section describes how to run iscsi from your cloned package.
Prerequisites
This guide starts by assuming that you can already build the standard SPDK distribution on your platform.
Once built, the binary will be in app/iscsi_tgt
.
If you want to kill the application by using signal, make sure use the SIGTERM, then the application will release all the shared memory resource before exit, the SIGKILL will make the shared memory resource have no chance to be released by applications, you may need to release the resource manually.
Configuring iSCSI Target
A iscsi_tgt
specific configuration file is used to configure the iSCSI target. A fully documented
example configuration file is located at etc/spdk/iscsi.conf.in
.
The configuration file is used to configure the SPDK iSCSI target. This file defines the following: TCP ports to use as iSCSI portals; general iSCSI parameters; initiator names and addresses to allow access to iSCSI target nodes; number and types of storage backends to export over iSCSI LUNs; iSCSI target node mappings between portal groups, initiator groups, and LUNs.
You should make a copy of the example configuration file, modify it to suit your environment, and then run the iscsi_tgt application and pass it the configuration file using the -c option. Right now, the target requires elevated privileges (root) to run.
app/iscsi_tgt/iscsi_tgt -c /path/to/iscsi.conf
Assigning CPU Cores to the iSCSI Target
SPDK uses the DPDK Environment Abstraction Layer to gain access to hardware resources such as huge memory pages and CPU core(s). DPDK EAL provides functions to assign threads to specific cores. To ensure the SPDK iSCSI target has the best performance, place the NICs and the NVMe devices on the same NUMA node and configure the target to run on CPU cores associated with that node. The following parameters in the configuration file are used to configure SPDK iSCSI target:
ReactorMask: A hexadecimal bit mask of the CPU cores that SPDK is allowed to execute work items on. The ReactorMask is located in the [Global] section of the configuration file. For example, to assign lcores 24,25,26 and 27 to iSCSI target work items, set the ReactorMask to:
ReactorMask 0xF000000
Configuring a LUN in the iSCSI Target
Each LUN in an iSCSI target node is associated with an SPDK block device. See @ref bdev for details on configuring SPDK block devices. The block device to LUN mappings are specified in the configuration file as:
[TargetNodeX]
LUN0 Malloc0
LUN1 Nvme0n1
This exports a malloc'd target. The disk is a RAM disk that is a chunk of memory allocated by iscsi in user space. It will use offload engine to do the copy job instead of memcpy if the system has enough DMA channels.
Configuring iSCSI Target via RPC method
In addition to the configuration file, the iSCSI target may also be configured via JSON-RPC calls. See @ref jsonrpc for details.
Add the portal group
python /path/to/spdk/scripts/rpc.py add_portal_group 1 127.0.0.1:3260
Add the initiator group
python /path/to/spdk/scripts/rpc.py add_initiator_group 2 ANY 127.0.0.1/32
Construct the backend block device
python /path/to/spdk/scripts/rpc.py construct_malloc_bdev -b MyBdev 64 512
Construct the target node
python /path/to/spdk/scripts/rpc.py construct_target_node Target3 Target3_alias MyBdev:0 1:2 64 0 0 0 1
Configuring iSCSI Initiator
The Linux initiator is open-iscsi.
Installing open-iscsi package Fedora:
yum install -y iscsi-initiator-utils
Ubuntu:
apt-get install -y open-iscsi
Setup
Edit /etc/iscsi/iscsid.conf
node.session.cmds_max = 4096
node.session.queue_depth = 128
iscsid must be restarted or receive SIGHUP for changes to take effect. To send SIGHUP, run:
killall -HUP iscsid
Recommended changes to /etc/sysctl.conf
net.ipv4.tcp_timestamps = 1
net.ipv4.tcp_sack = 0
net.ipv4.tcp_rmem = 10000000 10000000 10000000
net.ipv4.tcp_wmem = 10000000 10000000 10000000
net.ipv4.tcp_mem = 10000000 10000000 10000000
net.core.rmem_default = 524287
net.core.wmem_default = 524287
net.core.rmem_max = 524287
net.core.wmem_max = 524287
net.core.optmem_max = 524287
net.core.netdev_max_backlog = 300000
Discovery
Assume target is at 192.168.1.5
iscsiadm -m discovery -t sendtargets -p 192.168.1.5
Connect to target
iscsiadm -m node --login
At this point the iSCSI target should show up as SCSI disks. Check dmesg to see what they came up as.
Disconnect from target
iscsiadm -m node --logout
Deleting target node cache
iscsiadm -m node -o delete
This will cause the initiator to forget all previously discovered iSCSI target nodes.
Finding /dev/sdX nodes for iSCSI LUNs
iscsiadm -m session -P 3 | grep "Attached scsi disk" | awk '{print $4}'
This will show the /dev node name for each SCSI LUN in all logged in iSCSI sessions.
Tuning
After the targets are connected, they can be tuned. For example if /dev/sdc is an iSCSI disk then the following can be done: Set noop to scheduler
echo noop > /sys/block/sdc/queue/scheduler
Disable merging/coalescing (can be useful for precise workload measurements)
echo "2" > /sys/block/sdc/queue/nomerges
Increase requests for block queue
echo "1024" > /sys/block/sdc/queue/nr_requests
Vector Packet Processing
VPP (part of Fast Data - Input/Output project) is an extensible userspace framework providing networking functionality. It is build on idea of packet processing graph (see What is VPP?).
A detailed instructions for simplified steps 1-3 below, can be found on VPP Quick Start Guide.
SPDK supports VPP version 18.01.1.
1. Building VPP (optional)
Please skip this step if using already built packages.
Clone and checkout VPP
git clone https://gerrit.fd.io/r/vpp && cd vpp
git checkout v18.01.1
Install VPP build dependencies
make install-dep
Build and create .rpm packages
make pkg-rpm
Alternatively, build and create .deb packages
make pkg-deb
Packages can be found in vpp/build-root/
directory.
For more in depth instructions please see Building section in VPP documentation
Please note: VPP 18.01.1 does not support OpenSSL 1.1. It is suggested to install a compatibility package for compilation time.
sudo dnf install -y --allowerasing compat-openssl10-devel
Then reinstall latest OpenSSL devel package:
sudo dnf install -y --allowerasing openssl-devel
2. Installing VPP
Packages can be installed from distribution repository or built in previous step.
Minimal set of packages consists of vpp
, vpp-lib
and vpp-devel
.
Note: Please remove or modify /etc/sysctl.d/80-vpp.conf file with appropriate values dependent on number of hugepages that will be used on system.
3. Running VPP
VPP takes over any network interfaces that were bound to userspace driver, for details please see DPDK guide on Binding and Unbinding Network Ports to/from the Kernel Modules.
VPP is installed as service and disabled by default. To start VPP with default config:
sudo systemctl start vpp
Alternatively, use vpp
binary directly
sudo vpp unix {cli-listen /run/vpp/cli.sock}
A usefull tool is vppctl
, that allows to control running VPP instance.
Either by entering VPP configuration prompt
sudo vppctl
Or, by sending single command directly. For example to display interfaces within VPP:
sudo vppctl show interface
Example: Tap interfaces on single host
For functional test purpose a virtual tap interface can be created, so no additional network hardware is required. This will allow network communication between SPDK iSCSI target using VPP end of tap and kernel iSCSI initiator using the kernel part of tap. A single host is used in this scenario.
Create tap interface via VPP
vppctl tap connect tap0
vppctl set interface state tapcli-0 up
vppctl set interface ip address tapcli-0 10.0.0.1/24
vppctl show int addr
Assign address on kernel interface
sudo ip addr add 10.0.0.2/24 dev tap0
sudo ip link set tap0 up
To verify connectivity
ping 10.0.0.1
4. Building SPDK with VPP
Support for VPP can be built into SPDK by using configuration option.
configure --with-vpp
Alternatively, directory with built libraries can be pointed at and will be used for compilation instead of installed packages.
configure --with-vpp=/path/to/vpp/repo/build-root/vpp
5. Running SPDK with VPP
VPP application has to be started before SPDK iSCSI target, in order to enable usage of network interfaces. After SPDK iSCSI target initialization finishes, interfaces configured within VPP will be available to be configured as portal addresses. Please refer to @ref iscsi_rpc.
iSCSI Hotplug
At the iSCSI level, we provide the following support for Hotplug:
-
bdev/nvme: At the bdev/nvme level, we start one hotplug monitor which will call spdk_nvme_probe() periodically to get the hotplug events. We provide the private attach_cb and remove_cb for spdk_nvme_probe(). For the attach_cb, we will create the block device base on the NVMe device attached, and for the remove_cb, we will unregister the block device, which will also notify the upper level stack (for iSCSI target, the upper level stack is scsi/lun) to handle the hot-remove event.
-
scsi/lun: When the LUN receive the hot-remove notification from block device layer, the LUN will be marked as removed, and all the IOs after this point will return with check condition status. Then the LUN starts one poller which will wait for all the commands which have already been submitted to block device to return back; after all the commands return back, the LUN will be deleted.
Known bugs and limitations
For write command, if you want to test hotplug with write command which will cause r2t, for example 1M size IO, it will crash the iscsi tgt. For read command, if you want to test hotplug with large read IO, for example 1M size IO, it will probably crash the iscsi tgt.
@sa spdk_nvme_probe