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author | Philippe Mathieu-Daudé <philmd@linaro.org> | 2024-03-28 12:53:00 +0100 |
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committer | Philippe Mathieu-Daudé <philmd@linaro.org> | 2024-04-24 16:03:38 +0200 |
commit | 1dfd42c4264bbf47415a9e73f0d6b4e6a7cd7393 (patch) | |
tree | 602880437af7b8718208a7047da2eaaccb78b690 /docs | |
parent | a60e53fa8fecb3c2449f9be0f4dfc2afe17cf39e (diff) | |
download | qemu-1dfd42c4264bbf47415a9e73f0d6b4e6a7cd7393.zip qemu-1dfd42c4264bbf47415a9e73f0d6b4e6a7cd7393.tar.gz qemu-1dfd42c4264bbf47415a9e73f0d6b4e6a7cd7393.tar.bz2 |
hw/rdma: Remove deprecated pvrdma device and rdmacm-mux helper
The whole RDMA subsystem was deprecated in commit e9a54265f5
("hw/rdma: Deprecate the pvrdma device and the rdma subsystem")
released in v8.2.
Remove:
- PVRDMA device
- generated vmw_pvrdma/ directory from linux-headers
- rdmacm-mux tool from contrib/
Cc: Yuval Shaia <yuval.shaia.ml@gmail.com>
Cc: Marcel Apfelbaum <marcel.apfelbaum@gmail.com>
Signed-off-by: Philippe Mathieu-Daudé <philmd@linaro.org>
Reviewed-by: Thomas Huth <thuth@redhat.com>
Reviewed-by: Michael S. Tsirkin <mst@redhat.com>
Message-Id: <20240328130255.52257-2-philmd@linaro.org>
Diffstat (limited to 'docs')
-rw-r--r-- | docs/about/deprecated.rst | 9 | ||||
-rw-r--r-- | docs/about/removed-features.rst | 4 | ||||
-rw-r--r-- | docs/pvrdma.txt | 345 | ||||
-rw-r--r-- | docs/system/loongarch/virt.rst | 2 |
4 files changed, 5 insertions, 355 deletions
diff --git a/docs/about/deprecated.rst b/docs/about/deprecated.rst index 06090dd..7b8aafa 100644 --- a/docs/about/deprecated.rst +++ b/docs/about/deprecated.rst @@ -365,15 +365,6 @@ recommending to switch to their stable counterparts: - "Zve64f" should be replaced with "zve64f" - "Zve64d" should be replaced with "zve64d" -``-device pvrdma`` and the rdma subsystem (since 8.2) -^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ - -The pvrdma device and the whole rdma subsystem are in a bad shape and -without active maintenance. The QEMU project intends to remove this -device and subsystem from the code base in a future release without -replacement unless somebody steps up and improves the situation. - - Block device options '''''''''''''''''''' diff --git a/docs/about/removed-features.rst b/docs/about/removed-features.rst index 299c844..53ca08a 100644 --- a/docs/about/removed-features.rst +++ b/docs/about/removed-features.rst @@ -925,6 +925,10 @@ contains native support for this feature and thus use of the option ROM approach was obsolete. The native SeaBIOS support can be activated by using ``-machine graphics=off``. +``pvrdma`` and the RDMA subsystem (removed in 9.1) +'''''''''''''''''''''''''''''''''''''''''''''''''' + +The 'pvrdma' device and the whole RDMA subsystem have been removed. Related binaries ---------------- diff --git a/docs/pvrdma.txt b/docs/pvrdma.txt deleted file mode 100644 index 5c122fe..0000000 --- a/docs/pvrdma.txt +++ /dev/null @@ -1,345 +0,0 @@ -Paravirtualized RDMA Device (PVRDMA) -==================================== - - -1. Description -=============== -PVRDMA is the QEMU implementation of VMware's paravirtualized RDMA device. -It works with its Linux Kernel driver AS IS, no need for any special guest -modifications. - -While it complies with the VMware device, it can also communicate with bare -metal RDMA-enabled machines as peers. - -It does not require an RDMA HCA in the host, it can work with Soft-RoCE (rxe). - -It does not require the whole guest RAM to be pinned allowing memory -over-commit and, even if not implemented yet, migration support will be -possible with some HW assistance. - -A project presentation accompany this document: -- https://blog.linuxplumbersconf.org/2017/ocw/system/presentations/4730/original/lpc-2017-pvrdma-marcel-apfelbaum-yuval-shaia.pdf - - - -2. Setup -======== - - -2.1 Guest setup -=============== -Fedora 27+ kernels work out of the box, older distributions -require updating the kernel to 4.14 to include the pvrdma driver. - -However the libpvrdma library needed by User Level Software is still -not available as part of the distributions, so the rdma-core library -needs to be compiled and optionally installed. - -Please follow the instructions at: - https://github.com/linux-rdma/rdma-core.git - - -2.2 Host Setup -============== -The pvrdma backend is an ibdevice interface that can be exposed -either by a Soft-RoCE(rxe) device on machines with no RDMA device, -or an HCA SRIOV function(VF/PF). -Note that ibdevice interfaces can't be shared between pvrdma devices, -each one requiring a separate instance (rxe or SRIOV VF). - - -2.2.1 Soft-RoCE backend(rxe) -=========================== -A stable version of rxe is required, Fedora 27+ or a Linux -Kernel 4.14+ is preferred. - -The rdma_rxe module is part of the Linux Kernel but not loaded by default. -Install the User Level library (librxe) following the instructions from: -https://github.com/SoftRoCE/rxe-dev/wiki/rxe-dev:-Home - -Associate an ETH interface with rxe by running: - rxe_cfg add eth0 -An rxe0 ibdevice interface will be created and can be used as pvrdma backend. - - -2.2.2 RDMA device Virtual Function backend -========================================== -Nothing special is required, the pvrdma device can work not only with -Ethernet Links, but also Infinibands Links. -All is needed is an ibdevice with an active port, for Mellanox cards -will be something like mlx5_6 which can be the backend. - - -2.2.3 QEMU setup -================ -Configure QEMU with --enable-rdma flag, installing -the required RDMA libraries. - - - -3. Usage -======== - - -3.1 VM Memory settings -====================== -Currently the device is working only with memory backed RAM -and it must be mark as "shared": - -m 1G \ - -object memory-backend-ram,id=mb1,size=1G,share \ - -numa node,memdev=mb1 \ - - -3.2 MAD Multiplexer -=================== -MAD Multiplexer is a service that exposes MAD-like interface for VMs in -order to overcome the limitation where only single entity can register with -MAD layer to send and receive RDMA-CM MAD packets. - -To build rdmacm-mux run -# make rdmacm-mux - -Before running the rdmacm-mux make sure that both ib_cm and rdma_cm kernel -modules aren't loaded, otherwise the rdmacm-mux service will fail to start. - -The application accepts 3 command line arguments and exposes a UNIX socket -to pass control and data to it. --d rdma-device-name Name of RDMA device to register with --s unix-socket-path Path to unix socket to listen (default /var/run/rdmacm-mux) --p rdma-device-port Port number of RDMA device to register with (default 1) -The final UNIX socket file name is a concatenation of the 3 arguments so -for example for device mlx5_0 on port 2 this /var/run/rdmacm-mux-mlx5_0-2 -will be created. - -pvrdma requires this service. - -Please refer to contrib/rdmacm-mux for more details. - - -3.3 Service exposed by libvirt daemon -===================================== -The control over the RDMA device's GID table is done by updating the -device's Ethernet function addresses. -Usually the first GID entry is determined by the MAC address, the second by -the first IPv6 address and the third by the IPv4 address. Other entries can -be added by adding more IP addresses. The opposite is the same, i.e. -whenever an address is removed, the corresponding GID entry is removed. -The process is done by the network and RDMA stacks. Whenever an address is -added the ib_core driver is notified and calls the device driver add_gid -function which in turn update the device. -To support this in pvrdma device the device hooks into the create_bind and -destroy_bind HW commands triggered by pvrdma driver in guest. - -Whenever changed is made to the pvrdma port's GID table a special QMP -messages is sent to be processed by libvirt to update the address of the -backend Ethernet device. - -pvrdma requires that libvirt service will be up. - - -3.4 PCI devices settings -======================== -RoCE device exposes two functions - an Ethernet and RDMA. -To support it, pvrdma device is composed of two PCI functions, an Ethernet -device of type vmxnet3 on PCI slot 0 and a PVRDMA device on PCI slot 1. The -Ethernet function can be used for other Ethernet purposes such as IP. - - -3.5 Device parameters -===================== -- netdev: Specifies the Ethernet device function name on the host for - example enp175s0f0. For Soft-RoCE device (rxe) this would be the Ethernet - device used to create it. -- ibdev: The IB device name on host for example rxe0, mlx5_0 etc. -- mad-chardev: The name of the MAD multiplexer char device. -- ibport: In case of multi-port device (such as Mellanox's HCA) this - specify the port to use. If not set 1 will be used. -- dev-caps-max-mr-size: The maximum size of MR. -- dev-caps-max-qp: Maximum number of QPs. -- dev-caps-max-cq: Maximum number of CQs. -- dev-caps-max-mr: Maximum number of MRs. -- dev-caps-max-pd: Maximum number of PDs. -- dev-caps-max-ah: Maximum number of AHs. - -Notes: -- The first 3 parameters are mandatory settings, the rest have their - defaults. -- The last 8 parameters (the ones that prefixed by dev-caps) defines the top - limits but the final values is adjusted by the backend device limitations. -- netdev can be extracted from ibdev's sysfs - (/sys/class/infiniband/<ibdev>/device/net/) - - -3.6 Example -=========== -Define bridge device with vmxnet3 network backend: -<interface type='bridge'> - <mac address='56:b4:44:e9:62:dc'/> - <source bridge='bridge1'/> - <model type='vmxnet3'/> - <address type='pci' domain='0x0000' bus='0x00' slot='0x10' function='0x0' multifunction='on'/> -</interface> - -Define pvrdma device: -<qemu:commandline> - <qemu:arg value='-object'/> - <qemu:arg value='memory-backend-ram,id=mb1,size=1G,share'/> - <qemu:arg value='-numa'/> - <qemu:arg value='node,memdev=mb1'/> - <qemu:arg value='-chardev'/> - <qemu:arg value='socket,path=/var/run/rdmacm-mux-rxe0-1,id=mads'/> - <qemu:arg value='-device'/> - <qemu:arg value='pvrdma,addr=10.1,ibdev=rxe0,netdev=bridge0,mad-chardev=mads'/> -</qemu:commandline> - - - -4. Implementation details -========================= - - -4.1 Overview -============ -The device acts like a proxy between the Guest Driver and the host -ibdevice interface. -On configuration path: - - For every hardware resource request (PD/QP/CQ/...) the pvrdma will request - a resource from the backend interface, maintaining a 1-1 mapping - between the guest and host. -On data path: - - Every post_send/receive received from the guest will be converted into - a post_send/receive for the backend. The buffers data will not be touched - or copied resulting in near bare-metal performance for large enough buffers. - - Completions from the backend interface will result in completions for - the pvrdma device. - - -4.2 PCI BARs -============ -PCI Bars: - BAR 0 - MSI-X - MSI-X vectors: - (0) Command - used when execution of a command is completed. - (1) Async - not in use. - (2) Completion - used when a completion event is placed in - device's CQ ring. - BAR 1 - Registers - -------------------------------------------------------- - | VERSION | DSR | CTL | REQ | ERR | ICR | IMR | MAC | - -------------------------------------------------------- - DSR - Address of driver/device shared memory used - for the command channel, used for passing: - - General info such as driver version - - Address of 'command' and 'response' - - Address of async ring - - Address of device's CQ ring - - Device capabilities - CTL - Device control operations (activate, reset etc) - IMG - Set interrupt mask - REQ - Command execution register - ERR - Operation status - - BAR 2 - UAR - --------------------------------------------------------- - | QP_NUM | SEND/RECV Flag || CQ_NUM | ARM/POLL Flag | - --------------------------------------------------------- - - Offset 0 used for QP operations (send and recv) - - Offset 4 used for CQ operations (arm and poll) - - -4.3 Major flows -=============== - -4.3.1 Create CQ -=============== - - Guest driver - - Allocates pages for CQ ring - - Creates page directory (pdir) to hold CQ ring's pages - - Initializes CQ ring - - Initializes 'Create CQ' command object (cqe, pdir etc) - - Copies the command to 'command' address - - Writes 0 into REQ register - - Device - - Reads the request object from the 'command' address - - Allocates CQ object and initialize CQ ring based on pdir - - Creates the backend CQ - - Writes operation status to ERR register - - Posts command-interrupt to guest - - Guest driver - - Reads the HW response code from ERR register - -4.3.2 Create QP -=============== - - Guest driver - - Allocates pages for send and receive rings - - Creates page directory(pdir) to hold the ring's pages - - Initializes 'Create QP' command object (max_send_wr, - send_cq_handle, recv_cq_handle, pdir etc) - - Copies the object to 'command' address - - Write 0 into REQ register - - Device - - Reads the request object from 'command' address - - Allocates the QP object and initialize - - Send and recv rings based on pdir - - Send and recv ring state - - Creates the backend QP - - Writes the operation status to ERR register - - Posts command-interrupt to guest - - Guest driver - - Reads the HW response code from ERR register - -4.3.3 Post receive -================== - - Guest driver - - Initializes a wqe and place it on recv ring - - Write to qpn|qp_recv_bit (31) to QP offset in UAR - - Device - - Extracts qpn from UAR - - Walks through the ring and does the following for each wqe - - Prepares the backend CQE context to be used when - receiving completion from backend (wr_id, op_code, emu_cq_num) - - For each sge prepares backend sge - - Calls backend's post_recv - -4.3.4 Process backend events -============================ - - Done by a dedicated thread used to process backend events; - at initialization is attached to the device and creates - the communication channel. - - Thread main loop: - - Polls for completions - - Extracts QEMU _cq_num, wr_id and op_code from context - - Writes CQE to CQ ring - - Writes CQ number to device CQ - - Sends completion-interrupt to guest - - Deallocates context - - Acks the event to backend - - - -5. Limitations -============== -- The device obviously is limited by the Guest Linux Driver features implementation - of the VMware device API. -- Memory registration mechanism requires mremap for every page in the buffer in order - to map it to a contiguous virtual address range. Since this is not the data path - it should not matter much. If the default max mr size is increased, be aware that - memory registration can take up to 0.5 seconds for 1GB of memory. -- The device requires target page size to be the same as the host page size, - otherwise it will fail to init. -- QEMU cannot map guest RAM from a file descriptor if a pvrdma device is attached, - so it can't work with huge pages. The limitation will be addressed in the future, - however QEMU allocates Guest RAM with MADV_HUGEPAGE so if there are enough huge - pages available, QEMU will use them. QEMU will fail to init if the requirements - are not met. - - - -6. Performance -============== -By design the pvrdma device exits on each post-send/receive, so for small buffers -the performance is affected; however for medium buffers it will became close to -bare metal and from 1MB buffers and up it reaches bare metal performance. -(tested with 2 VMs, the pvrdma devices connected to 2 VFs of the same device) - -All the above assumes no memory registration is done on data path. diff --git a/docs/system/loongarch/virt.rst b/docs/system/loongarch/virt.rst index c37268b..06d034b 100644 --- a/docs/system/loongarch/virt.rst +++ b/docs/system/loongarch/virt.rst @@ -39,7 +39,7 @@ can be accessed by following steps. .. code-block:: bash - ./configure --disable-rdma --disable-pvrdma --prefix=/usr \ + ./configure --disable-rdma --prefix=/usr \ --target-list="loongarch64-softmmu" \ --disable-libiscsi --disable-libnfs --disable-libpmem \ --disable-glusterfs --enable-libusb --enable-usb-redir \ |