c9bde257f0
Change-Id: I32c09f5151db579312479d07c668b08fc404f399 Signed-off-by: Tomasz Kulasek <tomaszx.kulasek@intel.com> Reviewed-on: https://review.spdk.io/gerrit/c/spdk/spdk/+/652 Community-CI: Mellanox Build Bot Tested-by: SPDK CI Jenkins <sys_sgci@intel.com> Reviewed-by: Tomasz Zawadzki <tomasz.zawadzki@intel.com> Reviewed-by: Changpeng Liu <changpeng.liu@intel.com> Reviewed-by: Karol Latecki <karol.latecki@intel.com> Reviewed-by: Paul Luse <paul.e.luse@intel.com>
359 lines
16 KiB
Markdown
359 lines
16 KiB
Markdown
# NVMe Driver {#nvme}
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# In this document {#nvme_toc}
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* @ref nvme_intro
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* @ref nvme_examples
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* @ref nvme_interface
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* @ref nvme_design
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* @ref nvme_fabrics_host
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* @ref nvme_multi_process
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* @ref nvme_hotplug
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* @ref nvme_cuse
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# Introduction {#nvme_intro}
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The NVMe driver is a C library that may be linked directly into an application
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that provides direct, zero-copy data transfer to and from
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[NVMe SSDs](http://nvmexpress.org/). It is entirely passive, meaning that it spawns
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no threads and only performs actions in response to function calls from the
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application itself. The library controls NVMe devices by directly mapping the
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[PCI BAR](https://en.wikipedia.org/wiki/PCI_configuration_space) into the local
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process and performing [MMIO](https://en.wikipedia.org/wiki/Memory-mapped_I/O).
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I/O is submitted asynchronously via queue pairs and the general flow isn't
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entirely dissimilar from Linux's
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[libaio](http://man7.org/linux/man-pages/man2/io_submit.2.html).
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More recently, the library has been improved to also connect to remote NVMe
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devices via NVMe over Fabrics. Users may now call spdk_nvme_probe() on both
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local PCI busses and on remote NVMe over Fabrics discovery services. The API is
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otherwise unchanged.
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# Examples {#nvme_examples}
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## Getting Start with Hello World {#nvme_helloworld}
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There are a number of examples provided that demonstrate how to use the NVMe
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library. They are all in the [examples/nvme](https://github.com/spdk/spdk/tree/master/examples/nvme)
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directory in the repository. The best place to start is
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[hello_world](https://github.com/spdk/spdk/blob/master/examples/nvme/hello_world/hello_world.c).
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## Running Benchmarks with Fio Plugin {#nvme_fioplugin}
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SPDK provides a plugin to the very popular [fio](https://github.com/axboe/fio)
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tool for running some basic benchmarks. See the fio start up
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[guide](https://github.com/spdk/spdk/blob/master/examples/nvme/fio_plugin/)
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for more details.
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## Running Benchmarks with Perf Tool {#nvme_perf}
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NVMe perf utility in the [examples/nvme/perf](https://github.com/spdk/spdk/tree/master/examples/nvme/perf)
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is one of the examples which also can be used for performance tests. The fio
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tool is widely used because it is very flexible. However, that flexibility adds
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overhead and reduces the efficiency of SPDK. Therefore, SPDK provides a perf
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benchmarking tool which has minimal overhead during benchmarking. We have
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measured up to 2.6 times more IOPS/core when using perf vs. fio with the
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4K 100% Random Read workload. The perf benchmarking tool provides several
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run time options to support the most common workload. The following examples
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demonstrate how to use perf.
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Example: Using perf for 4K 100% Random Read workload to a local NVMe SSD for 300 seconds
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~~~{.sh}
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perf -q 128 -o 4096 -w randread -r 'trtype:PCIe traddr:0000:04:00.0' -t 300
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~~~
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Example: Using perf for 4K 100% Random Read workload to a remote NVMe SSD exported over the network via NVMe-oF
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~~~{.sh}
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perf -q 128 -o 4096 -w randread -r 'trtype:RDMA adrfam:IPv4 traddr:192.168.100.8 trsvcid:4420' -t 300
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~~~
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Example: Using perf for 4K 70/30 Random Read/Write mix workload to all local NVMe SSDs for 300 seconds
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~~~{.sh}
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perf -q 128 -o 4096 -w randrw -M 70 -t 300
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~~~
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Example: Using perf for extended LBA format CRC guard test to a local NVMe SSD,
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users must write to the SSD before reading the LBA from SSD
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~~~{.sh}
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perf -q 1 -o 4096 -w write -r 'trtype:PCIe traddr:0000:04:00.0' -t 300 -e 'PRACT=0,PRCKH=GUARD'
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perf -q 1 -o 4096 -w read -r 'trtype:PCIe traddr:0000:04:00.0' -t 200 -e 'PRACT=0,PRCKH=GUARD'
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~~~
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# Public Interface {#nvme_interface}
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- spdk/nvme.h
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Key Functions | Description
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------------------------------------------- | -----------
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spdk_nvme_probe() | @copybrief spdk_nvme_probe()
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spdk_nvme_ctrlr_alloc_io_qpair() | @copybrief spdk_nvme_ctrlr_alloc_io_qpair()
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spdk_nvme_ctrlr_get_ns() | @copybrief spdk_nvme_ctrlr_get_ns()
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spdk_nvme_ns_cmd_read() | @copybrief spdk_nvme_ns_cmd_read()
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spdk_nvme_ns_cmd_readv() | @copybrief spdk_nvme_ns_cmd_readv()
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spdk_nvme_ns_cmd_read_with_md() | @copybrief spdk_nvme_ns_cmd_read_with_md()
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spdk_nvme_ns_cmd_write() | @copybrief spdk_nvme_ns_cmd_write()
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spdk_nvme_ns_cmd_writev() | @copybrief spdk_nvme_ns_cmd_writev()
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spdk_nvme_ns_cmd_write_with_md() | @copybrief spdk_nvme_ns_cmd_write_with_md()
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spdk_nvme_ns_cmd_write_zeroes() | @copybrief spdk_nvme_ns_cmd_write_zeroes()
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spdk_nvme_ns_cmd_dataset_management() | @copybrief spdk_nvme_ns_cmd_dataset_management()
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spdk_nvme_ns_cmd_flush() | @copybrief spdk_nvme_ns_cmd_flush()
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spdk_nvme_qpair_process_completions() | @copybrief spdk_nvme_qpair_process_completions()
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spdk_nvme_ctrlr_cmd_admin_raw() | @copybrief spdk_nvme_ctrlr_cmd_admin_raw()
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spdk_nvme_ctrlr_process_admin_completions() | @copybrief spdk_nvme_ctrlr_process_admin_completions()
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spdk_nvme_ctrlr_cmd_io_raw() | @copybrief spdk_nvme_ctrlr_cmd_io_raw()
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spdk_nvme_ctrlr_cmd_io_raw_with_md() | @copybrief spdk_nvme_ctrlr_cmd_io_raw_with_md()
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# NVMe Driver Design {#nvme_design}
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## NVMe I/O Submission {#nvme_io_submission}
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I/O is submitted to an NVMe namespace using nvme_ns_cmd_xxx functions. The NVMe
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driver submits the I/O request as an NVMe submission queue entry on the queue
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pair specified in the command. The function returns immediately, prior to the
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completion of the command. The application must poll for I/O completion on each
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queue pair with outstanding I/O to receive completion callbacks by calling
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spdk_nvme_qpair_process_completions().
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@sa spdk_nvme_ns_cmd_read, spdk_nvme_ns_cmd_write, spdk_nvme_ns_cmd_dataset_management,
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spdk_nvme_ns_cmd_flush, spdk_nvme_qpair_process_completions
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### Fused operations {#nvme_fuses}
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To "fuse" two commands, the first command should have the SPDK_NVME_IO_FLAGS_FUSE_FIRST
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io flag set, and the next one should have the SPDK_NVME_IO_FLAGS_FUSE_SECOND.
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In addition, the following rules must be met to execute two commands as an atomic unit:
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- The commands shall be inserted next to each other in the same submission queue.
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- The LBA range, should be the same for the two commands.
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E.g. To send fused compare and write operation user must call spdk_nvme_ns_cmd_compare
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followed with spdk_nvme_ns_cmd_write and make sure no other operations are submitted
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in between on the same queue, like in example below:
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~~~
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rc = spdk_nvme_ns_cmd_compare(ns, qpair, cmp_buf, 0, 1, nvme_fused_first_cpl_cb,
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NULL, SPDK_NVME_CMD_FUSE_FIRST);
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if (rc != 0) {
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...
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}
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rc = spdk_nvme_ns_cmd_write(ns, qpair, write_buf, 0, 1, nvme_fused_second_cpl_cb,
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NULL, SPDK_NVME_CMD_FUSE_SECOND);
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if (rc != 0) {
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...
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}
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~~~
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The NVMe specification currently defines compare-and-write as a fused operation.
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Support for compare-and-write is reported by the controller flag
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SPDK_NVME_CTRLR_COMPARE_AND_WRITE_SUPPORTED.
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### Scaling Performance {#nvme_scaling}
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NVMe queue pairs (struct spdk_nvme_qpair) provide parallel submission paths for
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I/O. I/O may be submitted on multiple queue pairs simultaneously from different
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threads. Queue pairs contain no locks or atomics, however, so a given queue
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pair may only be used by a single thread at a time. This requirement is not
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enforced by the NVMe driver (doing so would require a lock), and violating this
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requirement results in undefined behavior.
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The number of queue pairs allowed is dictated by the NVMe SSD itself. The
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specification allows for thousands, but most devices support between 32
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and 128. The specification makes no guarantees about the performance available from
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each queue pair, but in practice the full performance of a device is almost
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always achievable using just one queue pair. For example, if a device claims to
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be capable of 450,000 I/O per second at queue depth 128, in practice it does
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not matter if the driver is using 4 queue pairs each with queue depth 32, or a
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single queue pair with queue depth 128.
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Given the above, the easiest threading model for an application using SPDK is
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to spawn a fixed number of threads in a pool and dedicate a single NVMe queue
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pair to each thread. A further improvement would be to pin each thread to a
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separate CPU core, and often the SPDK documentation will use "CPU core" and
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"thread" interchangeably because we have this threading model in mind.
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The NVMe driver takes no locks in the I/O path, so it scales linearly in terms
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of performance per thread as long as a queue pair and a CPU core are dedicated
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to each new thread. In order to take full advantage of this scaling,
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applications should consider organizing their internal data structures such
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that data is assigned exclusively to a single thread. All operations that
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require that data should be done by sending a request to the owning thread.
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This results in a message passing architecture, as opposed to a locking
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architecture, and will result in superior scaling across CPU cores.
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## NVMe Driver Internal Memory Usage {#nvme_memory_usage}
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The SPDK NVMe driver provides a zero-copy data transfer path, which means that
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there are no data buffers for I/O commands. However, some Admin commands have
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data copies depending on the API used by the user.
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Each queue pair has a number of trackers used to track commands submitted by the
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caller. The number trackers for I/O queues depend on the users' input for queue
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size and the value read from controller capabilities register field Maximum Queue
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Entries Supported(MQES, 0 based value). Each tracker has a fixed size 4096 Bytes,
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so the maximum memory used for each I/O queue is: (MQES + 1) * 4 KiB.
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I/O queue pairs can be allocated in host memory, this is used for most NVMe controllers,
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some NVMe controllers which can support Controller Memory Buffer may put I/O queue
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pairs at controllers' PCI BAR space, SPDK NVMe driver can put I/O submission queue
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into controller memory buffer, it depends on users' input and controller capabilities.
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Each submission queue entry (SQE) and completion queue entry (CQE) consumes 64 bytes
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and 16 bytes respectively. Therefore, the maximum memory used for each I/O queue
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pair is (MQES + 1) * (64 + 16) Bytes.
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# NVMe over Fabrics Host Support {#nvme_fabrics_host}
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The NVMe driver supports connecting to remote NVMe-oF targets and
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interacting with them in the same manner as local NVMe SSDs.
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## Specifying Remote NVMe over Fabrics Targets {#nvme_fabrics_trid}
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The method for connecting to a remote NVMe-oF target is very similar
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to the normal enumeration process for local PCIe-attached NVMe devices.
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To connect to a remote NVMe over Fabrics subsystem, the user may call
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spdk_nvme_probe() with the `trid` parameter specifying the address of
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the NVMe-oF target.
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The caller may fill out the spdk_nvme_transport_id structure manually
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or use the spdk_nvme_transport_id_parse() function to convert a
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human-readable string representation into the required structure.
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The spdk_nvme_transport_id may contain the address of a discovery service
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or a single NVM subsystem. If a discovery service address is specified,
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the NVMe library will call the spdk_nvme_probe() `probe_cb` for each
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discovered NVM subsystem, which allows the user to select the desired
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subsystems to be attached. Alternatively, if the address specifies a
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single NVM subsystem directly, the NVMe library will call `probe_cb`
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for just that subsystem; this allows the user to skip the discovery step
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and connect directly to a subsystem with a known address.
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## RDMA Limitations
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Please refer to NVMe-oF target's @ref nvmf_rdma_limitations
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# NVMe Multi Process {#nvme_multi_process}
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This capability enables the SPDK NVMe driver to support multiple processes accessing the
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same NVMe device. The NVMe driver allocates critical structures from shared memory, so
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that each process can map that memory and create its own queue pairs or share the admin
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queue. There is a limited number of I/O queue pairs per NVMe controller.
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The primary motivation for this feature is to support management tools that can attach
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to long running applications, perform some maintenance work or gather information, and
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then detach.
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## Configuration {#nvme_multi_process_configuration}
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DPDK EAL allows different types of processes to be spawned, each with different permissions
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on the hugepage memory used by the applications.
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There are two types of processes:
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1. a primary process which initializes the shared memory and has full privileges and
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2. a secondary process which can attach to the primary process by mapping its shared memory
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regions and perform NVMe operations including creating queue pairs.
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This feature is enabled by default and is controlled by selecting a value for the shared
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memory group ID. This ID is a positive integer and two applications with the same shared
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memory group ID will share memory. The first application with a given shared memory group
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ID will be considered the primary and all others secondary.
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Example: identical shm_id and non-overlapping core masks
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~~~{.sh}
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./perf options [AIO device(s)]...
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[-c core mask for I/O submission/completion]
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[-i shared memory group ID]
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./perf -q 1 -o 4096 -w randread -c 0x1 -t 60 -i 1
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./perf -q 8 -o 131072 -w write -c 0x10 -t 60 -i 1
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~~~
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## Limitations {#nvme_multi_process_limitations}
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1. Two processes sharing memory may not share any cores in their core mask.
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2. If a primary process exits while secondary processes are still running, those processes
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will continue to run. However, a new primary process cannot be created.
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3. Applications are responsible for coordinating access to logical blocks.
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4. If a process exits unexpectedly, the allocated memory will be released when the last
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process exits.
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@sa spdk_nvme_probe, spdk_nvme_ctrlr_process_admin_completions
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# NVMe Hotplug {#nvme_hotplug}
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At the NVMe driver level, we provide the following support for Hotplug:
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1. Hotplug events detection:
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The user of the NVMe library can call spdk_nvme_probe() periodically to detect
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hotplug events. The probe_cb, followed by the attach_cb, will be called for each
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new device detected. The user may optionally also provide a remove_cb that will be
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called if a previously attached NVMe device is no longer present on the system.
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All subsequent I/O to the removed device will return an error.
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2. Hot remove NVMe with IO loads:
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When a device is hot removed while I/O is occurring, all access to the PCI BAR will
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result in a SIGBUS error. The NVMe driver automatically handles this case by installing
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a SIGBUS handler and remapping the PCI BAR to a new, placeholder memory location.
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This means I/O in flight during a hot remove will complete with an appropriate error
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code and will not crash the application.
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@sa spdk_nvme_probe
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# NVMe Character Devices {#nvme_cuse}
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This feature is considered as experimental.
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![NVMe character devices processing diagram](nvme_cuse.svg)
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For each controller as well as namespace, character devices are created in the
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locations:
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~~~{.sh}
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/dev/spdk/nvmeX
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/dev/spdk/nvmeXnY
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...
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~~~
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Where X is unique SPDK NVMe controller index and Y is namespace id.
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Requests from CUSE are handled by pthreads when controller and namespaces are created.
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Those pass the I/O or admin commands via a ring to a thread that processes them using
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nvme_io_msg_process().
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Ioctls that request information attained when attaching NVMe controller receive an
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immediate response, without passing them through the ring.
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This interface reserves one qpair for sending down the I/O for each controller.
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## Enabling cuse support for NVMe
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Cuse support is disabled by default. To enable support for NVMe devices SPDK
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must be compiled with "./configure --with-nvme-cuse".
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## Limitations
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NVMe namespaces are created as character devices and their use may be limited for
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tools expecting block devices.
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Sysfs is not updated by SPDK.
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SPDK NVMe CUSE creates nodes in "/dev/spdk/" directory to explicitly differentiate
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from other devices. Tools that only search in the "/dev" directory might not work
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with SPDK NVMe CUSE.
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SCSI to NVMe Translation Layer is not implemented. Tools that are using this layer to
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identify, manage or operate device might not work properly or their use may be limited.
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### Examples of using smartctl
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smartctl tool recognizes device type based on the device path. If none of expected
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patterns match, SCSI translation layer is used to identify device.
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To use smartctl '-d nvme' parameter must be used in addition to full path to
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the NVMe device.
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~~~{.sh}
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smartctl -d nvme -i /dev/spdk/nvme0
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smartctl -d nvme -H /dev/spdk/nvme1
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...
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~~~
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