From 19fcec84d8d7d21e796c7624e521b60d28ee21ed Mon Sep 17 00:00:00 2001 From: Daniel Baumann Date: Sun, 7 Apr 2024 20:45:59 +0200 Subject: Adding upstream version 16.2.11+ds. Signed-off-by: Daniel Baumann --- src/spdk/doc/bdev.md | 602 +++++++++++++++++++++++++++++++++++++++++++++++++++ 1 file changed, 602 insertions(+) create mode 100644 src/spdk/doc/bdev.md (limited to 'src/spdk/doc/bdev.md') diff --git a/src/spdk/doc/bdev.md b/src/spdk/doc/bdev.md new file mode 100644 index 000000000..9f842943f --- /dev/null +++ b/src/spdk/doc/bdev.md @@ -0,0 +1,602 @@ +# Block Device User Guide {#bdev} + +# Introduction {#bdev_ug_introduction} + +The SPDK block device layer, often simply called *bdev*, is a C library +intended to be equivalent to the operating system block storage layer that +often sits immediately above the device drivers in a traditional kernel +storage stack. Specifically, this library provides the following +functionality: + +* A pluggable module API for implementing block devices that interface with different types of block storage devices. +* Driver modules for NVMe, malloc (ramdisk), Linux AIO, virtio-scsi, Ceph RBD, Pmem and Vhost-SCSI Initiator and more. +* An application API for enumerating and claiming SPDK block devices and then performing operations (read, write, unmap, etc.) on those devices. +* Facilities to stack block devices to create complex I/O pipelines, including logical volume management (lvol) and partition support (GPT). +* Configuration of block devices via JSON-RPC. +* Request queueing, timeout, and reset handling. +* Multiple, lockless queues for sending I/O to block devices. + +Bdev module creates abstraction layer that provides common API for all devices. +User can use available bdev modules or create own module with any type of +device underneath (please refer to @ref bdev_module for details). SPDK +provides also vbdev modules which creates block devices on existing bdev. For +example @ref bdev_ug_logical_volumes or @ref bdev_ug_gpt + +# Prerequisites {#bdev_ug_prerequisites} + +This guide assumes that you can already build the standard SPDK distribution +on your platform. The block device layer is a C library with a single public +header file named bdev.h. All SPDK configuration described in following +chapters is done by using JSON-RPC commands. SPDK provides a python-based +command line tool for sending RPC commands located at `scripts/rpc.py`. User +can list available commands by running this script with `-h` or `--help` flag. +Additionally user can retrieve currently supported set of RPC commands +directly from SPDK application by running `scripts/rpc.py rpc_get_methods`. +Detailed help for each command can be displayed by adding `-h` flag as a +command parameter. + +# General Purpose RPCs {#bdev_ug_general_rpcs} + +## bdev_get_bdevs {#bdev_ug_get_bdevs} + +List of currently available block devices including detailed information about +them can be get by using `bdev_get_bdevs` RPC command. User can add optional +parameter `name` to get details about specified by that name bdev. + +Example response + +~~~ +{ + "num_blocks": 32768, + "assigned_rate_limits": { + "rw_ios_per_sec": 10000, + "rw_mbytes_per_sec": 20 + }, + "supported_io_types": { + "reset": true, + "nvme_admin": false, + "unmap": true, + "read": true, + "write_zeroes": true, + "write": true, + "flush": true, + "nvme_io": false + }, + "driver_specific": {}, + "claimed": false, + "block_size": 4096, + "product_name": "Malloc disk", + "name": "Malloc0" +} +~~~ + +## bdev_set_qos_limit {#bdev_set_qos_limit} + +Users can use the `bdev_set_qos_limit` RPC command to enable, adjust, and disable +rate limits on an existing bdev. Two types of rate limits are supported: +IOPS and bandwidth. The rate limits can be enabled, adjusted, and disabled at any +time for the specified bdev. The bdev name is a required parameter for this +RPC command and at least one of `rw_ios_per_sec` and `rw_mbytes_per_sec` must be +specified. When both rate limits are enabled, the first met limit will +take effect. The value 0 may be specified to disable the corresponding rate +limit. Users can run this command with `-h` or `--help` for more information. + +## Histograms {#rpc_bdev_histogram} + +The `bdev_enable_histogram` RPC command allows to enable or disable gathering +latency data for specified bdev. Histogram can be downloaded by the user by +calling `bdev_get_histogram` and parsed using scripts/histogram.py script. + +Example command + +`rpc.py bdev_enable_histogram Nvme0n1 --enable` + +The command will enable gathering data for histogram on Nvme0n1 device. + +`rpc.py bdev_get_histogram Nvme0n1 | histogram.py` + +The command will download gathered histogram data. The script will parse +the data and show table containing IO count for latency ranges. + +`rpc.py bdev_enable_histogram Nvme0n1 --disable` + +The command will disable histogram on Nvme0n1 device. + +# Ceph RBD {#bdev_config_rbd} + +The SPDK RBD bdev driver provides SPDK block layer access to Ceph RADOS block +devices (RBD). Ceph RBD devices are accessed via librbd and librados libraries +to access the RADOS block device exported by Ceph. To create Ceph bdev RPC +command `bdev_rbd_create` should be used. + +Example command + +`rpc.py bdev_rbd_create rbd foo 512` + +This command will create a bdev that represents the 'foo' image from a pool called 'rbd'. + +To remove a block device representation use the bdev_rbd_delete command. + +`rpc.py bdev_rbd_delete Rbd0` + +To resize a bdev use the bdev_rbd_resize command. + +`rpc.py bdev_rbd_resize Rbd0 4096` + +This command will resize the Rbd0 bdev to 4096 MiB. + +# Compression Virtual Bdev Module {#bdev_config_compress} + +The compression bdev module can be configured to provide compression/decompression +services for an underlying thinly provisioned logical volume. Although the underlying +module can be anything (i.e. NVME bdev) the overall compression benefits will not be realized +unless the data stored on disk is placed appropriately. The compression vbdev module +relies on an internal SPDK library called `reduce` to accomplish this, see @ref reduce +for detailed information. + +The vbdev module relies on the DPDK CompressDev Framework to provide all compression +functionality. The framework provides support for many different software only +compression modules as well as hardware assisted support for Intel QAT. At this +time the vbdev module supports the DPDK drivers for ISAL and QAT. + +Persistent memory is used to store metadata associated with the layout of the data on the +backing device. SPDK relies on [PMDK](http://pmem.io/pmdk/) to interface persistent memory so any hardware +supported by PMDK should work. If the directory for PMEM supplied upon vbdev creation does +not point to persistent memory (i.e. a regular filesystem) performance will be severely +impacted. The vbdev module and reduce libraries were designed to use persistent memory for +any production use. + +Example command + +`rpc.py bdev_compress_create -p /pmem_files -b myLvol` + +In this example, a compression vbdev is created using persistent memory that is mapped to +the directory `pmem_files` on top of the existing thinly provisioned logical volume `myLvol`. +The resulting compression bdev will be named `COMP_LVS/myLvol` where LVS is the name of the +logical volume store that `myLvol` resides on. + +The logical volume is referred to as the backing device and once the compression vbdev is +created it cannot be separated from the persistent memory file that will be created in +the specified directory. If the persistent memory file is not available, the compression +vbdev will also not be available. + +By default the vbdev module will choose the QAT driver if the hardware and drivers are +available and loaded. If not, it will revert to the software-only ISAL driver. By using +the following command, the driver may be specified however this is not persistent so it +must be done either upon creation or before the underlying logical volume is loaded to +be honored. In the example below, `0` is telling the vbdev module to use QAT if available +otherwise use ISAL, this is the default and if sufficient the command is not required. Passing +a value of 1 tells the driver to use QAT and if not available then the creation or loading +the vbdev should fail to create or load. A value of '2' as shown below tells the module +to use ISAL and if for some reason it is not available, the vbdev should fail to create or load. + +`rpc.py compress_set_pmd -p 2` + +To remove a compression vbdev, use the following command which will also delete the PMEM +file. If the logical volume is deleted the PMEM file will not be removed and the +compression vbdev will not be available. + +`rpc.py bdev_compress_delete COMP_LVS/myLvol` + +To list compression volumes that are only available for deletion because their PMEM file +was missing use the following. The name parameter is optional and if not included will list +all volumes, if used it will return the name or an error that the device does not exist. + +`rpc.py bdev_compress_get_orphans --name COMP_Nvme0n1` + +# Crypto Virtual Bdev Module {#bdev_config_crypto} + +The crypto virtual bdev module can be configured to provide at rest data encryption +for any underlying bdev. The module relies on the DPDK CryptoDev Framework to provide +all cryptographic functionality. The framework provides support for many different software +only cryptographic modules as well hardware assisted support for the Intel QAT board. The +framework also provides support for cipher, hash, authentication and AEAD functions. At this +time the SPDK virtual bdev module supports cipher only as follows: + +- AESN-NI Multi Buffer Crypto Poll Mode Driver: RTE_CRYPTO_CIPHER_AES128_CBC +- Intel(R) QuickAssist (QAT) Crypto Poll Mode Driver: RTE_CRYPTO_CIPHER_AES128_CBC + (Note: QAT is functional however is marked as experimental until the hardware has + been fully integrated with the SPDK CI system.) + +In order to support using the bdev block offset (LBA) as the initialization vector (IV), +the crypto module break up all I/O into crypto operations of a size equal to the block +size of the underlying bdev. For example, a 4K I/O to a bdev with a 512B block size, +would result in 8 cryptographic operations. + +For reads, the buffer provided to the crypto module will be used as the destination buffer +for unencrypted data. For writes, however, a temporary scratch buffer is used as the +destination buffer for encryption which is then passed on to the underlying bdev as the +write buffer. This is done to avoid encrypting the data in the original source buffer which +may cause problems in some use cases. + +Example command + +`rpc.py bdev_crypto_create NVMe1n1 CryNvmeA crypto_aesni_mb 0123456789123456` + +This command will create a crypto vbdev called 'CryNvmeA' on top of the NVMe bdev +'NVMe1n1' and will use the DPDK software driver 'crypto_aesni_mb' and the key +'0123456789123456'. + +To remove the vbdev use the bdev_crypto_delete command. + +`rpc.py bdev_crypto_delete CryNvmeA` + +# Delay Bdev Module {#bdev_config_delay} + +The delay vbdev module is intended to apply a predetermined additional latency on top of a lower +level bdev. This enables the simulation of the latency characteristics of a device during the functional +or scalability testing of an SPDK application. For example, to simulate the effect of drive latency when +processing I/Os, one could configure a NULL bdev with a delay bdev on top of it. + +The delay bdev module is not intended to provide a high fidelity replication of a specific NVMe drive's latency, +instead it's main purpose is to provide a "big picture" understanding of how a generic latency affects a given +application. + +A delay bdev is created using the `bdev_delay_create` RPC. This rpc takes 6 arguments, one for the name +of the delay bdev and one for the name of the base bdev. The remaining four arguments represent the following +latency values: average read latency, average write latency, p99 read latency, and p99 write latency. +Within the context of the delay bdev p99 latency means that one percent of the I/O will be delayed by at +least by the value of the p99 latency before being completed to the upper level protocol. All of the latency values +are measured in microseconds. + +Example command: + +`rpc.py bdev_delay_create -b Null0 -d delay0 -r 10 --nine-nine-read-latency 50 -w 30 --nine-nine-write-latency 90` + +This command will create a delay bdev with average read and write latencies of 10 and 30 microseconds and p99 read +and write latencies of 50 and 90 microseconds respectively. + +A delay bdev can be deleted using the `bdev_delay_delete` RPC + +Example command: + +`rpc.py bdev_delay_delete delay0` + +# GPT (GUID Partition Table) {#bdev_config_gpt} + +The GPT virtual bdev driver is enabled by default and does not require any configuration. +It will automatically detect @ref bdev_ug_gpt on any attached bdev and will create +possibly multiple virtual bdevs. + +## SPDK GPT partition table {#bdev_ug_gpt} + +The SPDK partition type GUID is `7c5222bd-8f5d-4087-9c00-bf9843c7b58c`. Existing SPDK bdevs +can be exposed as Linux block devices via NBD and then can be partitioned with +standard partitioning tools. After partitioning, the bdevs will need to be deleted and +attached again for the GPT bdev module to see any changes. NBD kernel module must be +loaded first. To create NBD bdev user should use `nbd_start_disk` RPC command. + +Example command + +`rpc.py nbd_start_disk Malloc0 /dev/nbd0` + +This will expose an SPDK bdev `Malloc0` under the `/dev/nbd0` block device. + +To remove NBD device user should use `nbd_stop_disk` RPC command. + +Example command + +`rpc.py nbd_stop_disk /dev/nbd0` + +To display full or specified nbd device list user should use `nbd_get_disks` RPC command. + +Example command + +`rpc.py nbd_stop_disk -n /dev/nbd0` + +## Creating a GPT partition table using NBD {#bdev_ug_gpt_create_part} + +~~~ +# Expose bdev Nvme0n1 as kernel block device /dev/nbd0 by JSON-RPC +rpc.py nbd_start_disk Nvme0n1 /dev/nbd0 + +# Create GPT partition table. +parted -s /dev/nbd0 mklabel gpt + +# Add a partition consuming 50% of the available space. +parted -s /dev/nbd0 mkpart MyPartition '0%' '50%' + +# Change the partition type to the SPDK GUID. +# sgdisk is part of the gdisk package. +sgdisk -t 1:7c5222bd-8f5d-4087-9c00-bf9843c7b58c /dev/nbd0 + +# Stop the NBD device (stop exporting /dev/nbd0). +rpc.py nbd_stop_disk /dev/nbd0 + +# Now Nvme0n1 is configured with a GPT partition table, and +# the first partition will be automatically exposed as +# Nvme0n1p1 in SPDK applications. +~~~ + +# iSCSI bdev {#bdev_config_iscsi} + +The SPDK iSCSI bdev driver depends on libiscsi and hence is not enabled by default. +In order to use it, build SPDK with an extra `--with-iscsi-initiator` configure option. + +The following command creates an `iSCSI0` bdev from a single LUN exposed at given iSCSI URL +with `iqn.2016-06.io.spdk:init` as the reported initiator IQN. + +`rpc.py bdev_iscsi_create -b iSCSI0 -i iqn.2016-06.io.spdk:init --url iscsi://127.0.0.1/iqn.2016-06.io.spdk:disk1/0` + +The URL is in the following format: +`iscsi://[[%]@][:]//` + +# Linux AIO bdev {#bdev_config_aio} + +The SPDK AIO bdev driver provides SPDK block layer access to Linux kernel block +devices or a file on a Linux filesystem via Linux AIO. Note that O_DIRECT is +used and thus bypasses the Linux page cache. This mode is probably as close to +a typical kernel based target as a user space target can get without using a +user-space driver. To create AIO bdev RPC command `bdev_aio_create` should be +used. + +Example commands + +`rpc.py bdev_aio_create /dev/sda aio0` + +This command will create `aio0` device from /dev/sda. + +`rpc.py bdev_aio_create /tmp/file file 4096` + +This command will create `file` device with block size 4096 from /tmp/file. + +To delete an aio bdev use the bdev_aio_delete command. + +`rpc.py bdev_aio_delete aio0` + +# OCF Virtual bdev {#bdev_config_cas} + +OCF virtual bdev module is based on [Open CAS Framework](https://github.com/Open-CAS/ocf) - a +high performance block storage caching meta-library. +To enable the module, configure SPDK using `--with-ocf` flag. +OCF bdev can be used to enable caching for any underlying bdev. + +Below is an example command for creating OCF bdev: + +`rpc.py bdev_ocf_create Cache1 wt Malloc0 Nvme0n1` + +This command will create new OCF bdev `Cache1` having bdev `Malloc0` as caching-device +and `Nvme0n1` as core-device and initial cache mode `Write-Through`. +`Malloc0` will be used as cache for `Nvme0n1`, so data written to `Cache1` will be present +on `Nvme0n1` eventually. +By default, OCF will be configured with cache line size equal 4KiB +and non-volatile metadata will be disabled. + +To remove `Cache1`: + +`rpc.py bdev_ocf_delete Cache1` + +During removal OCF-cache will be stopped and all cached data will be written to the core device. + +Note that OCF has a per-device RAM requirement +of about 56000 + _cache device size_ * 58 / _cache line size_ (in bytes). +To get more information on OCF +please visit [OCF documentation](https://open-cas.github.io/). + +# Malloc bdev {#bdev_config_malloc} + +Malloc bdevs are ramdisks. Because of its nature they are volatile. They are created from hugepage memory given to SPDK +application. + +# Null {#bdev_config_null} + +The SPDK null bdev driver is a dummy block I/O target that discards all writes and returns undefined +data for reads. It is useful for benchmarking the rest of the bdev I/O stack with minimal block +device overhead and for testing configurations that can't easily be created with the Malloc bdev. +To create Null bdev RPC command `bdev_null_create` should be used. + +Example command + +`rpc.py bdev_null_create Null0 8589934592 4096` + +This command will create an 8 petabyte `Null0` device with block size 4096. + +To delete a null bdev use the bdev_null_delete command. + +`rpc.py bdev_null_delete Null0` + +# NVMe bdev {#bdev_config_nvme} + +There are two ways to create block device based on NVMe device in SPDK. First +way is to connect local PCIe drive and second one is to connect NVMe-oF device. +In both cases user should use `bdev_nvme_attach_controller` RPC command to achieve that. + +Example commands + +`rpc.py bdev_nvme_attach_controller -b NVMe1 -t PCIe -a 0000:01:00.0` + +This command will create NVMe bdev of physical device in the system. + +`rpc.py bdev_nvme_attach_controller -b Nvme0 -t RDMA -a 192.168.100.1 -f IPv4 -s 4420 -n nqn.2016-06.io.spdk:cnode1` + +This command will create NVMe bdev of NVMe-oF resource. + +To remove an NVMe controller use the bdev_nvme_detach_controller command. + +`rpc.py bdev_nvme_detach_controller Nvme0` + +This command will remove NVMe bdev named Nvme0. + +## NVMe bdev character device {#bdev_config_nvme_cuse} + +This feature is considered as experimental. + +Example commands + +`rpc.py bdev_nvme_cuse_register -n Nvme0 -p spdk/nvme0` + +This command will register /dev/spdk/nvme0 character device associated with Nvme0 +controller. If there are namespaces created on Nvme0 controller, for each namespace +device /dev/spdk/nvme0nX is created. + +Cuse devices are removed from system, when NVMe controller is detached or unregistered +with command: + +`rpc.py bdev_nvme_cuse_unregister -n Nvme0` + +# Logical volumes {#bdev_ug_logical_volumes} + +The Logical Volumes library is a flexible storage space management system. It allows +creating and managing virtual block devices with variable size on top of other bdevs. +The SPDK Logical Volume library is built on top of @ref blob. For detailed description +please refer to @ref lvol. + +## Logical volume store {#bdev_ug_lvol_store} + +Before creating any logical volumes (lvols), an lvol store has to be created first on +selected block device. Lvol store is lvols vessel responsible for managing underlying +bdev space assignment to lvol bdevs and storing metadata. To create lvol store user +should use using `bdev_lvol_create_lvstore` RPC command. + +Example command + +`rpc.py bdev_lvol_create_lvstore Malloc2 lvs -c 4096` + +This will create lvol store named `lvs` with cluster size 4096, build on top of +`Malloc2` bdev. In response user will be provided with uuid which is unique lvol store +identifier. + +User can get list of available lvol stores using `bdev_lvol_get_lvstores` RPC command (no +parameters available). + +Example response + +~~~ +{ + "uuid": "330a6ab2-f468-11e7-983e-001e67edf35d", + "base_bdev": "Malloc2", + "free_clusters": 8190, + "cluster_size": 8192, + "total_data_clusters": 8190, + "block_size": 4096, + "name": "lvs" +} +~~~ + +To delete lvol store user should use `bdev_lvol_delete_lvstore` RPC command. + +Example commands + +`rpc.py bdev_lvol_delete_lvstore -u 330a6ab2-f468-11e7-983e-001e67edf35d` + +`rpc.py bdev_lvol_delete_lvstore -l lvs` + +## Lvols {#bdev_ug_lvols} + +To create lvols on existing lvol store user should use `bdev_lvol_create` RPC command. +Each created lvol will be represented by new bdev. + +Example commands + +`rpc.py bdev_lvol_create lvol1 25 -l lvs` + +`rpc.py bdev_lvol_create lvol2 25 -u 330a6ab2-f468-11e7-983e-001e67edf35d` + +# RAID {#bdev_ug_raid} + +RAID virtual bdev module provides functionality to combine any SPDK bdevs into +one RAID bdev. Currently SPDK supports only RAID 0. RAID functionality does not +store on-disk metadata on the member disks, so user must recreate the RAID +volume when restarting application. User may specify member disks to create RAID +volume event if they do not exists yet - as the member disks are registered at +a later time, the RAID module will claim them and will surface the RAID volume +after all of the member disks are available. It is allowed to use disks of +different sizes - the smallest disk size will be the amount of space used on +each member disk. + +Example commands + +`rpc.py bdev_raid_create -n Raid0 -z 64 -r 0 -b "lvol0 lvol1 lvol2 lvol3"` + +`rpc.py bdev_raid_get_bdevs` + +`rpc.py bdev_raid_delete Raid0` + +# Passthru {#bdev_config_passthru} + +The SPDK Passthru virtual block device module serves as an example of how to write a +virtual block device module. It implements the required functionality of a vbdev module +and demonstrates some other basic features such as the use of per I/O context. + +Example commands + +`rpc.py bdev_passthru_create -b aio -p pt` + +`rpc.py bdev_passthru_delete pt` + +# Pmem {#bdev_config_pmem} + +The SPDK pmem bdev driver uses pmemblk pool as the target for block I/O operations. For +details on Pmem memory please refer to PMDK documentation on http://pmem.io website. +First, user needs to configure SPDK to include PMDK support: + +`configure --with-pmdk` + +To create pmemblk pool for use with SPDK user should use `bdev_pmem_create_pool` RPC command. + +Example command + +`rpc.py bdev_pmem_create_pool /path/to/pmem_pool 25 4096` + +To get information on created pmem pool file user can use `bdev_pmem_get_pool_info` RPC command. + +Example command + +`rpc.py bdev_pmem_get_pool_info /path/to/pmem_pool` + +To remove pmem pool file user can use `bdev_pmem_delete_pool` RPC command. + +Example command + +`rpc.py bdev_pmem_delete_pool /path/to/pmem_pool` + +To create bdev based on pmemblk pool file user should use `bdev_pmem_create ` RPC +command. + +Example command + +`rpc.py bdev_pmem_create /path/to/pmem_pool -n pmem` + +To remove a block device representation use the bdev_pmem_delete command. + +`rpc.py bdev_pmem_delete pmem` + +# Virtio Block {#bdev_config_virtio_blk} + +The Virtio-Block driver allows creating SPDK bdevs from Virtio-Block devices. + +The following command creates a Virtio-Block device named `VirtioBlk0` from a vhost-user +socket `/tmp/vhost.0` exposed directly by SPDK @ref vhost. Optional `vq-count` and +`vq-size` params specify number of request queues and queue depth to be used. + +`rpc.py bdev_virtio_attach_controller --dev-type blk --trtype user --traddr /tmp/vhost.0 --vq-count 2 --vq-size 512 VirtioBlk0` + +The driver can be also used inside QEMU-based VMs. The following command creates a Virtio +Block device named `VirtioBlk0` from a Virtio PCI device at address `0000:00:01.0`. +The entire configuration will be read automatically from PCI Configuration Space. It will +reflect all parameters passed to QEMU's vhost-user-scsi-pci device. + +`rpc.py bdev_virtio_attach_controller --dev-type blk --trtype pci --traddr 0000:01:00.0 VirtioBlk1` + +Virtio-Block devices can be removed with the following command + +`rpc.py bdev_virtio_detach_controller VirtioBlk0` + +# Virtio SCSI {#bdev_config_virtio_scsi} + +The Virtio-SCSI driver allows creating SPDK block devices from Virtio-SCSI LUNs. + +Virtio-SCSI bdevs are created the same way as Virtio-Block ones. + +`rpc.py bdev_virtio_attach_controller --dev-type scsi --trtype user --traddr /tmp/vhost.0 --vq-count 2 --vq-size 512 VirtioScsi0` + +`rpc.py bdev_virtio_attach_controller --dev-type scsi --trtype pci --traddr 0000:01:00.0 VirtioScsi0` + +Each Virtio-SCSI device may export up to 64 block devices named VirtioScsi0t0 ~ VirtioScsi0t63, +one LUN (LUN0) per SCSI device. The above 2 commands will output names of all exposed bdevs. + +Virtio-SCSI devices can be removed with the following command + +`rpc.py bdev_virtio_detach_controller VirtioScsi0` + +Removing a Virtio-SCSI device will destroy all its bdevs. -- cgit v1.2.3