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313 lines
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===================================================
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PCI Express I/O Virtualization Resource on Powerenv
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===================================================
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Wei Yang <weiyang@linux.vnet.ibm.com>
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Benjamin Herrenschmidt <benh@au1.ibm.com>
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Bjorn Helgaas <bhelgaas@google.com>
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26 Aug 2014
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This document describes the requirement from hardware for PCI MMIO resource
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sizing and assignment on PowerKVM and how generic PCI code handles this
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requirement. The first two sections describe the concepts of Partitionable
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Endpoints and the implementation on P8 (IODA2). The next two sections talks
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about considerations on enabling SRIOV on IODA2.
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1. Introduction to Partitionable Endpoints
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==========================================
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A Partitionable Endpoint (PE) is a way to group the various resources
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associated with a device or a set of devices to provide isolation between
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partitions (i.e., filtering of DMA, MSIs etc.) and to provide a mechanism
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to freeze a device that is causing errors in order to limit the possibility
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of propagation of bad data.
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There is thus, in HW, a table of PE states that contains a pair of "frozen"
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state bits (one for MMIO and one for DMA, they get set together but can be
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cleared independently) for each PE.
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When a PE is frozen, all stores in any direction are dropped and all loads
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return all 1's value. MSIs are also blocked. There's a bit more state that
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captures things like the details of the error that caused the freeze etc., but
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that's not critical.
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The interesting part is how the various PCIe transactions (MMIO, DMA, ...)
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are matched to their corresponding PEs.
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The following section provides a rough description of what we have on P8
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(IODA2). Keep in mind that this is all per PHB (PCI host bridge). Each PHB
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is a completely separate HW entity that replicates the entire logic, so has
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its own set of PEs, etc.
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2. Implementation of Partitionable Endpoints on P8 (IODA2)
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==========================================================
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P8 supports up to 256 Partitionable Endpoints per PHB.
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* Inbound
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For DMA, MSIs and inbound PCIe error messages, we have a table (in
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memory but accessed in HW by the chip) that provides a direct
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correspondence between a PCIe RID (bus/dev/fn) with a PE number.
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We call this the RTT.
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- For DMA we then provide an entire address space for each PE that can
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contain two "windows", depending on the value of PCI address bit 59.
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Each window can be configured to be remapped via a "TCE table" (IOMMU
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translation table), which has various configurable characteristics
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not described here.
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- For MSIs, we have two windows in the address space (one at the top of
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the 32-bit space and one much higher) which, via a combination of the
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address and MSI value, will result in one of the 2048 interrupts per
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bridge being triggered. There's a PE# in the interrupt controller
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descriptor table as well which is compared with the PE# obtained from
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the RTT to "authorize" the device to emit that specific interrupt.
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- Error messages just use the RTT.
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* Outbound. That's where the tricky part is.
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Like other PCI host bridges, the Power8 IODA2 PHB supports "windows"
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from the CPU address space to the PCI address space. There is one M32
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window and sixteen M64 windows. They have different characteristics.
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First what they have in common: they forward a configurable portion of
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the CPU address space to the PCIe bus and must be naturally aligned
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power of two in size. The rest is different:
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- The M32 window:
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* Is limited to 4GB in size.
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* Drops the top bits of the address (above the size) and replaces
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them with a configurable value. This is typically used to generate
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32-bit PCIe accesses. We configure that window at boot from FW and
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don't touch it from Linux; it's usually set to forward a 2GB
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portion of address space from the CPU to PCIe
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0x8000_0000..0xffff_ffff. (Note: The top 64KB are actually
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reserved for MSIs but this is not a problem at this point; we just
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need to ensure Linux doesn't assign anything there, the M32 logic
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ignores that however and will forward in that space if we try).
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* It is divided into 256 segments of equal size. A table in the chip
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maps each segment to a PE#. That allows portions of the MMIO space
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to be assigned to PEs on a segment granularity. For a 2GB window,
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the segment granularity is 2GB/256 = 8MB.
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Now, this is the "main" window we use in Linux today (excluding
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SR-IOV). We basically use the trick of forcing the bridge MMIO windows
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onto a segment alignment/granularity so that the space behind a bridge
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can be assigned to a PE.
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Ideally we would like to be able to have individual functions in PEs
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but that would mean using a completely different address allocation
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scheme where individual function BARs can be "grouped" to fit in one or
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more segments.
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- The M64 windows:
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* Must be at least 256MB in size.
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* Do not translate addresses (the address on PCIe is the same as the
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address on the PowerBus). There is a way to also set the top 14
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bits which are not conveyed by PowerBus but we don't use this.
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* Can be configured to be segmented. When not segmented, we can
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specify the PE# for the entire window. When segmented, a window
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has 256 segments; however, there is no table for mapping a segment
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to a PE#. The segment number *is* the PE#.
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* Support overlaps. If an address is covered by multiple windows,
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there's a defined ordering for which window applies.
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We have code (fairly new compared to the M32 stuff) that exploits that
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for large BARs in 64-bit space:
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We configure an M64 window to cover the entire region of address space
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that has been assigned by FW for the PHB (about 64GB, ignore the space
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for the M32, it comes out of a different "reserve"). We configure it
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as segmented.
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Then we do the same thing as with M32, using the bridge alignment
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trick, to match to those giant segments.
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Since we cannot remap, we have two additional constraints:
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- We do the PE# allocation *after* the 64-bit space has been assigned
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because the addresses we use directly determine the PE#. We then
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update the M32 PE# for the devices that use both 32-bit and 64-bit
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spaces or assign the remaining PE# to 32-bit only devices.
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- We cannot "group" segments in HW, so if a device ends up using more
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than one segment, we end up with more than one PE#. There is a HW
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mechanism to make the freeze state cascade to "companion" PEs but
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that only works for PCIe error messages (typically used so that if
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you freeze a switch, it freezes all its children). So we do it in
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SW. We lose a bit of effectiveness of EEH in that case, but that's
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the best we found. So when any of the PEs freezes, we freeze the
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other ones for that "domain". We thus introduce the concept of
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"master PE" which is the one used for DMA, MSIs, etc., and "secondary
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PEs" that are used for the remaining M64 segments.
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We would like to investigate using additional M64 windows in "single
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PE" mode to overlay over specific BARs to work around some of that, for
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example for devices with very large BARs, e.g., GPUs. It would make
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sense, but we haven't done it yet.
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3. Considerations for SR-IOV on PowerKVM
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========================================
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* SR-IOV Background
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The PCIe SR-IOV feature allows a single Physical Function (PF) to
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support several Virtual Functions (VFs). Registers in the PF's SR-IOV
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Capability control the number of VFs and whether they are enabled.
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When VFs are enabled, they appear in Configuration Space like normal
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PCI devices, but the BARs in VF config space headers are unusual. For
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a non-VF device, software uses BARs in the config space header to
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discover the BAR sizes and assign addresses for them. For VF devices,
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software uses VF BAR registers in the *PF* SR-IOV Capability to
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discover sizes and assign addresses. The BARs in the VF's config space
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header are read-only zeros.
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When a VF BAR in the PF SR-IOV Capability is programmed, it sets the
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base address for all the corresponding VF(n) BARs. For example, if the
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PF SR-IOV Capability is programmed to enable eight VFs, and it has a
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1MB VF BAR0, the address in that VF BAR sets the base of an 8MB region.
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This region is divided into eight contiguous 1MB regions, each of which
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is a BAR0 for one of the VFs. Note that even though the VF BAR
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describes an 8MB region, the alignment requirement is for a single VF,
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i.e., 1MB in this example.
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There are several strategies for isolating VFs in PEs:
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- M32 window: There's one M32 window, and it is split into 256
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equally-sized segments. The finest granularity possible is a 256MB
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window with 1MB segments. VF BARs that are 1MB or larger could be
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mapped to separate PEs in this window. Each segment can be
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individually mapped to a PE via the lookup table, so this is quite
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flexible, but it works best when all the VF BARs are the same size. If
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they are different sizes, the entire window has to be small enough that
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the segment size matches the smallest VF BAR, which means larger VF
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BARs span several segments.
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- Non-segmented M64 window: A non-segmented M64 window is mapped entirely
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to a single PE, so it could only isolate one VF.
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- Single segmented M64 windows: A segmented M64 window could be used just
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like the M32 window, but the segments can't be individually mapped to
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PEs (the segment number is the PE#), so there isn't as much
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flexibility. A VF with multiple BARs would have to be in a "domain" of
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multiple PEs, which is not as well isolated as a single PE.
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- Multiple segmented M64 windows: As usual, each window is split into 256
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equally-sized segments, and the segment number is the PE#. But if we
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use several M64 windows, they can be set to different base addresses
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and different segment sizes. If we have VFs that each have a 1MB BAR
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and a 32MB BAR, we could use one M64 window to assign 1MB segments and
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another M64 window to assign 32MB segments.
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Finally, the plan to use M64 windows for SR-IOV, which will be described
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more in the next two sections. For a given VF BAR, we need to
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effectively reserve the entire 256 segments (256 * VF BAR size) and
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position the VF BAR to start at the beginning of a free range of
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segments/PEs inside that M64 window.
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The goal is of course to be able to give a separate PE for each VF.
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The IODA2 platform has 16 M64 windows, which are used to map MMIO
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range to PE#. Each M64 window defines one MMIO range and this range is
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divided into 256 segments, with each segment corresponding to one PE.
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We decide to leverage this M64 window to map VFs to individual PEs, since
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SR-IOV VF BARs are all the same size.
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But doing so introduces another problem: total_VFs is usually smaller
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than the number of M64 window segments, so if we map one VF BAR directly
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to one M64 window, some part of the M64 window will map to another
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device's MMIO range.
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IODA supports 256 PEs, so segmented windows contain 256 segments, so if
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total_VFs is less than 256, we have the situation in Figure 1.0, where
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segments [total_VFs, 255] of the M64 window may map to some MMIO range on
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other devices::
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0 1 total_VFs - 1
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+------+------+- -+------+------+
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| | | ... | | |
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+------+------+- -+------+------+
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VF(n) BAR space
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0 1 total_VFs - 1 255
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+------+------+- -+------+------+- -+------+------+
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| | | ... | | | ... | | |
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+------+------+- -+------+------+- -+------+------+
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M64 window
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Figure 1.0 Direct map VF(n) BAR space
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Our current solution is to allocate 256 segments even if the VF(n) BAR
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space doesn't need that much, as shown in Figure 1.1::
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0 1 total_VFs - 1 255
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+------+------+- -+------+------+- -+------+------+
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| | | ... | | | ... | | |
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+------+------+- -+------+------+- -+------+------+
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VF(n) BAR space + extra
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0 1 total_VFs - 1 255
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+------+------+- -+------+------+- -+------+------+
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| | | ... | | | ... | | |
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+------+------+- -+------+------+- -+------+------+
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M64 window
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Figure 1.1 Map VF(n) BAR space + extra
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Allocating the extra space ensures that the entire M64 window will be
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assigned to this one SR-IOV device and none of the space will be
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available for other devices. Note that this only expands the space
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reserved in software; there are still only total_VFs VFs, and they only
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respond to segments [0, total_VFs - 1]. There's nothing in hardware that
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responds to segments [total_VFs, 255].
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4. Implications for the Generic PCI Code
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========================================
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The PCIe SR-IOV spec requires that the base of the VF(n) BAR space be
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aligned to the size of an individual VF BAR.
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In IODA2, the MMIO address determines the PE#. If the address is in an M32
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window, we can set the PE# by updating the table that translates segments
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to PE#s. Similarly, if the address is in an unsegmented M64 window, we can
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set the PE# for the window. But if it's in a segmented M64 window, the
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segment number is the PE#.
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Therefore, the only way to control the PE# for a VF is to change the base
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of the VF(n) BAR space in the VF BAR. If the PCI core allocates the exact
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amount of space required for the VF(n) BAR space, the VF BAR value is fixed
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and cannot be changed.
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On the other hand, if the PCI core allocates additional space, the VF BAR
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value can be changed as long as the entire VF(n) BAR space remains inside
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the space allocated by the core.
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Ideally the segment size will be the same as an individual VF BAR size.
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Then each VF will be in its own PE. The VF BARs (and therefore the PE#s)
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are contiguous. If VF0 is in PE(x), then VF(n) is in PE(x+n). If we
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allocate 256 segments, there are (256 - numVFs) choices for the PE# of VF0.
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If the segment size is smaller than the VF BAR size, it will take several
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segments to cover a VF BAR, and a VF will be in several PEs. This is
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possible, but the isolation isn't as good, and it reduces the number of PE#
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choices because instead of consuming only numVFs segments, the VF(n) BAR
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space will consume (numVFs * n) segments. That means there aren't as many
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available segments for adjusting base of the VF(n) BAR space.
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