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ivshmem: Rewrite specification document
This started as an attempt to update ivshmem_device_spec.txt for clarity, accuracy and completeness while working on its code, and quickly became a full rewrite. Since the diff would be useless anyway, I'm using the opportunity to rename the file to ivshmem-spec.txt. I tried hard to ensure the new text contradicts neither the old text nor the code. If the new text contradicts the old text but not the code, it's probably a bug in the old text. If the new text contradicts both, its probably a bug in the new text. Signed-off-by: Markus Armbruster <armbru@redhat.com> Reviewed-by: Marc-André Lureau <marcandre.lureau@redhat.com> Message-Id: <1458066895-20632-11-git-send-email-armbru@redhat.com>
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docs/specs/ivshmem-spec.txt
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docs/specs/ivshmem-spec.txt
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= Device Specification for Inter-VM shared memory device =
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The Inter-VM shared memory device (ivshmem) is designed to share a
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memory region between multiple QEMU processes running different guests
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and the host. In order for all guests to be able to pick up the
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shared memory area, it is modeled by QEMU as a PCI device exposing
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said memory to the guest as a PCI BAR.
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The device can use a shared memory object on the host directly, or it
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can obtain one from an ivshmem server.
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In the latter case, the device can additionally interrupt its peers, and
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get interrupted by its peers.
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== Configuring the ivshmem PCI device ==
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There are two basic configurations:
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- Just shared memory: -device ivshmem,shm=NAME,...
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This uses shared memory object NAME.
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- Shared memory plus interrupts: -device ivshmem,chardev=CHR,vectors=N,...
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An ivshmem server must already be running on the host. The device
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connects to the server's UNIX domain socket via character device
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CHR.
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Each peer gets assigned a unique ID by the server. IDs must be
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between 0 and 65535.
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Interrupts are message-signaled by default (MSI-X). With msi=off
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the device has no MSI-X capability, and uses legacy INTx instead.
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vectors=N configures the number of vectors to use.
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For more details on ivshmem device properties, see The QEMU Emulator
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User Documentation (qemu-doc.*).
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== The ivshmem PCI device's guest interface ==
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The device has vendor ID 1af4, device ID 1110, revision 0.
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=== PCI BARs ===
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The ivshmem PCI device has two or three BARs:
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- BAR0 holds device registers (256 Byte MMIO)
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- BAR1 holds MSI-X table and PBA (only when using MSI-X)
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- BAR2 maps the shared memory object
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There are two ways to use this device:
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- If you only need the shared memory part, BAR2 suffices. This way,
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you have access to the shared memory in the guest and can use it as
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you see fit. Memnic, for example, uses ivshmem this way from guest
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user space (see http://dpdk.org/browse/memnic).
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- If you additionally need the capability for peers to interrupt each
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other, you need BAR0 and, if using MSI-X, BAR1. You will most
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likely want to write a kernel driver to handle interrupts. Requires
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the device to be configured for interrupts, obviously.
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If the device is configured for interrupts, BAR2 is initially invalid.
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It becomes safely accessible only after the ivshmem server provided
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the shared memory. Guest software should wait for the IVPosition
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register (described below) to become non-negative before accessing
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BAR2.
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The device is not capable to tell guest software whether it is
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configured for interrupts.
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=== PCI device registers ===
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BAR 0 contains the following registers:
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Offset Size Access On reset Function
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0 4 read/write 0 Interrupt Mask
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bit 0: peer interrupt
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bit 1..31: reserved
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4 4 read/write 0 Interrupt Status
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bit 0: peer interrupt
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bit 1..31: reserved
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8 4 read-only 0 or -1 IVPosition
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12 4 write-only N/A Doorbell
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bit 0..15: vector
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bit 16..31: peer ID
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16 240 none N/A reserved
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Software should only access the registers as specified in column
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"Access". Reserved bits should be ignored on read, and preserved on
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write.
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Interrupt Status and Mask Register together control the legacy INTx
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interrupt when the device has no MSI-X capability: INTx is asserted
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when the bit-wise AND of Status and Mask is non-zero and the device
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has no MSI-X capability. Interrupt Status Register bit 0 becomes 1
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when an interrupt request from a peer is received. Reading the
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register clears it.
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IVPosition Register: if the device is not configured for interrupts,
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this is zero. Else, it's -1 for a short while after reset, then
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changes to the device's ID (between 0 and 65535).
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There is no good way for software to find out whether the device is
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configured for interrupts. A positive IVPosition means interrupts,
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but zero could be either. The initial -1 cannot be reliably observed.
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Doorbell Register: writing this register requests to interrupt a peer.
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The written value's high 16 bits are the ID of the peer to interrupt,
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and its low 16 bits select an interrupt vector.
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If the device is not configured for interrupts, the write is ignored.
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If the interrupt hasn't completed setup, the write is ignored. The
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device is not capable to tell guest software whether setup is
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complete. Interrupts can regress to this state on migration.
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If the peer with the requested ID isn't connected, or it has fewer
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interrupt vectors connected, the write is ignored. The device is not
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capable to tell guest software what peers are connected, or how many
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interrupt vectors are connected.
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If the peer doesn't use MSI-X, its Interrupt Status register is set to
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1. This asserts INTx unless masked by the Interrupt Mask register.
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The device is not capable to communicate the interrupt vector to guest
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software then.
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If the peer uses MSI-X, the interrupt for this vector becomes pending.
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There is no way for software to clear the pending bit, and a polling
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mode of operation is therefore impossible with MSI-X.
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With multiple MSI-X vectors, different vectors can be used to indicate
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different events have occurred. The semantics of interrupt vectors
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are left to the application.
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== Interrupt infrastructure ==
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When configured for interrupts, the peers share eventfd objects in
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addition to shared memory. The shared resources are managed by an
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ivshmem server.
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=== The ivshmem server ===
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The server listens on a UNIX domain socket.
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For each new client that connects to the server, the server
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- picks an ID,
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- creates eventfd file descriptors for the interrupt vectors,
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- sends the ID and the file descriptor for the shared memory to the
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new client,
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- sends connect notifications for the new client to the other clients
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(these contain file descriptors for sending interrupts),
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- sends connect notifications for the other clients to the new client,
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and
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- sends interrupt setup messages to the new client (these contain file
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descriptors for receiving interrupts).
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When a client disconnects from the server, the server sends disconnect
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notifications to the other clients.
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The next section describes the protocol in detail.
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If the server terminates without sending disconnect notifications for
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its connected clients, the clients can elect to continue. They can
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communicate with each other normally, but won't receive disconnect
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notification on disconnect, and no new clients can connect. There is
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no way for the clients to connect to a restarted server. The device
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is not capable to tell guest software whether the server is still up.
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Example server code is in contrib/ivshmem-server/. Not to be used in
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production. It assumes all clients use the same number of interrupt
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vectors.
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A standalone client is in contrib/ivshmem-client/. It can be useful
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for debugging.
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=== The ivshmem Client-Server Protocol ===
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An ivshmem device configured for interrupts connects to an ivshmem
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server. This section details the protocol between the two.
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The connection is one-way: the server sends messages to the client.
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Each message consists of a single 8 byte little-endian signed number,
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and may be accompanied by a file descriptor via SCM_RIGHTS. Both
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client and server close the connection on error.
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On connect, the server sends the following messages in order:
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1. The protocol version number, currently zero. The client should
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close the connection on receipt of versions it can't handle.
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2. The client's ID. This is unique among all clients of this server.
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IDs must be between 0 and 65535, because the Doorbell register
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provides only 16 bits for them.
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3. The number -1, accompanied by the file descriptor for the shared
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memory.
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4. Connect notifications for existing other clients, if any. This is
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a peer ID (number between 0 and 65535 other than the client's ID),
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repeated N times. Each repetition is accompanied by one file
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descriptor. These are for interrupting the peer with that ID using
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vector 0,..,N-1, in order. If the client is configured for fewer
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vectors, it closes the extra file descriptors. If it is configured
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for more, the extra vectors remain unconnected.
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5. Interrupt setup. This is the client's own ID, repeated N times.
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Each repetition is accompanied by one file descriptor. These are
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for receiving interrupts from peers using vector 0,..,N-1, in
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order. If the client is configured for fewer vectors, it closes
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the extra file descriptors. If it is configured for more, the
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extra vectors remain unconnected.
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From then on, the server sends these kinds of messages:
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6. Connection / disconnection notification. This is a peer ID.
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- If the number comes with a file descriptor, it's a connection
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notification, exactly like in step 4.
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- Else, it's a disconnection notification for the peer with that ID.
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Known bugs:
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* The protocol changed incompatibly in QEMU 2.5. Before, messages
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were native endian long, and there was no version number.
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* The protocol is poorly designed.
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=== The ivshmem Client-Client Protocol ===
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An ivshmem device configured for interrupts receives eventfd file
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descriptors for interrupting peers and getting interrupted by peers
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from the server, as explained in the previous section.
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To interrupt a peer, the device writes the 8-byte integer 1 in native
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byte order to the respective file descriptor.
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To receive an interrupt, the device reads and discards as many 8-byte
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integers as it can.
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@ -1,161 +0,0 @@
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Device Specification for Inter-VM shared memory device
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------------------------------------------------------
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The Inter-VM shared memory device is designed to share a memory region (created
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on the host via the POSIX shared memory API) between multiple QEMU processes
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running different guests. In order for all guests to be able to pick up the
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shared memory area, it is modeled by QEMU as a PCI device exposing said memory
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to the guest as a PCI BAR.
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The memory region does not belong to any guest, but is a POSIX memory object on
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the host. The host can access this shared memory if needed.
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The device also provides an optional communication mechanism between guests
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sharing the same memory object. More details about that in the section 'Guest to
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guest communication' section.
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The Inter-VM PCI device
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-----------------------
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From the VM point of view, the ivshmem PCI device supports three BARs.
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- BAR0 is a 1 Kbyte MMIO region to support registers and interrupts when MSI is
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not used.
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- BAR1 is used for MSI-X when it is enabled in the device.
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- BAR2 is used to access the shared memory object.
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It is your choice how to use the device but you must choose between two
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behaviors :
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- basically, if you only need the shared memory part, you will map BAR2.
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This way, you have access to the shared memory in guest and can use it as you
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see fit (memnic, for example, uses it in userland
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http://dpdk.org/browse/memnic).
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- BAR0 and BAR1 are used to implement an optional communication mechanism
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through interrupts in the guests. If you need an event mechanism between the
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guests accessing the shared memory, you will most likely want to write a
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kernel driver that will handle interrupts. See details in the section 'Guest
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to guest communication' section.
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The behavior is chosen when starting your QEMU processes:
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- no communication mechanism needed, the first QEMU to start creates the shared
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memory on the host, subsequent QEMU processes will use it.
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- communication mechanism needed, an ivshmem server must be started before any
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QEMU processes, then each QEMU process connects to the server unix socket.
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For more details on the QEMU ivshmem parameters, see qemu-doc documentation.
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Guest to guest communication
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----------------------------
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This section details the communication mechanism between the guests accessing
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the ivhsmem shared memory.
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*ivshmem server*
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This server code is available in qemu.git/contrib/ivshmem-server.
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The server must be started on the host before any guest.
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It creates a shared memory object then waits for clients to connect on a unix
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socket. All the messages are little-endian int64_t integer.
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For each client (QEMU process) that connects to the server:
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- the server sends a protocol version, if client does not support it, the client
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closes the communication,
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- the server assigns an ID for this client and sends this ID to him as the first
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message,
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- the server sends a fd to the shared memory object to this client,
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- the server creates a new set of host eventfds associated to the new client and
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sends this set to all already connected clients,
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- finally, the server sends all the eventfds sets for all clients to the new
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client.
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The server signals all clients when one of them disconnects.
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The client IDs are limited to 16 bits because of the current implementation (see
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Doorbell register in 'PCI device registers' subsection). Hence only 65536
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clients are supported.
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All the file descriptors (fd to the shared memory, eventfds for each client)
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are passed to clients using SCM_RIGHTS over the server unix socket.
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Apart from the current ivshmem implementation in QEMU, an ivshmem client has
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been provided in qemu.git/contrib/ivshmem-client for debug.
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*QEMU as an ivshmem client*
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At initialisation, when creating the ivshmem device, QEMU first receives a
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protocol version and closes communication with server if it does not match.
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Then, QEMU gets its ID from the server then makes it available through BAR0
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IVPosition register for the VM to use (see 'PCI device registers' subsection).
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QEMU then uses the fd to the shared memory to map it to BAR2.
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eventfds for all other clients received from the server are stored to implement
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BAR0 Doorbell register (see 'PCI device registers' subsection).
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Finally, eventfds assigned to this QEMU process are used to send interrupts in
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this VM.
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*PCI device registers*
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From the VM point of view, the ivshmem PCI device supports 4 registers of
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32-bits each.
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enum ivshmem_registers {
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IntrMask = 0,
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IntrStatus = 4,
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IVPosition = 8,
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Doorbell = 12
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};
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The first two registers are the interrupt mask and status registers. Mask and
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status are only used with pin-based interrupts. They are unused with MSI
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interrupts.
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Status Register: The status register is set to 1 when an interrupt occurs.
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Mask Register: The mask register is bitwise ANDed with the interrupt status
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and the result will raise an interrupt if it is non-zero. However, since 1 is
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the only value the status will be set to, it is only the first bit of the mask
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that has any effect. Therefore interrupts can be masked by setting the first
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bit to 0 and unmasked by setting the first bit to 1.
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IVPosition Register: The IVPosition register is read-only and reports the
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guest's ID number. The guest IDs are non-negative integers. When using the
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server, since the server is a separate process, the VM ID will only be set when
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the device is ready (shared memory is received from the server and accessible
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via the device). If the device is not ready, the IVPosition will return -1.
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Applications should ensure that they have a valid VM ID before accessing the
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shared memory.
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Doorbell Register: To interrupt another guest, a guest must write to the
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Doorbell register. The doorbell register is 32-bits, logically divided into
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two 16-bit fields. The high 16-bits are the guest ID to interrupt and the low
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16-bits are the interrupt vector to trigger. The semantics of the value
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written to the doorbell depends on whether the device is using MSI or a regular
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pin-based interrupt. In short, MSI uses vectors while regular interrupts set
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the status register.
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Regular Interrupts
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If regular interrupts are used (due to either a guest not supporting MSI or the
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user specifying not to use them on startup) then the value written to the lower
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16-bits of the Doorbell register results is arbitrary and will trigger an
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interrupt in the destination guest.
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Message Signalled Interrupts
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An ivshmem device may support multiple MSI vectors. If so, the lower 16-bits
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written to the Doorbell register must be between 0 and the maximum number of
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vectors the guest supports. The lower 16 bits written to the doorbell is the
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MSI vector that will be raised in the destination guest. The number of MSI
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vectors is configurable but it is set when the VM is started.
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The important thing to remember with MSI is that it is only a signal, no status
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is set (since MSI interrupts are not shared). All information other than the
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interrupt itself should be communicated via the shared memory region. Devices
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supporting multiple MSI vectors can use different vectors to indicate different
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events have occurred. The semantics of interrupt vectors are left to the
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user's discretion.
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