Author | Tokens | Token Proportion | Commits | Commit Proportion |
---|---|---|---|---|
Oliver O'Halloran | 2274 | 96.60% | 12 | 52.17% |
Benjamin Herrenschmidt | 30 | 1.27% | 4 | 17.39% |
Guo Chao | 20 | 0.85% | 1 | 4.35% |
Gavin Shan | 13 | 0.55% | 1 | 4.35% |
Andrew Donnellan | 10 | 0.42% | 1 | 4.35% |
Wei Yang | 3 | 0.13% | 1 | 4.35% |
Björn Helgaas | 2 | 0.08% | 1 | 4.35% |
Michael Ellerman | 1 | 0.04% | 1 | 4.35% |
Julia Lawall | 1 | 0.04% | 1 | 4.35% |
Total | 2354 | 23 |
// SPDX-License-Identifier: GPL-2.0-or-later #include <linux/kernel.h> #include <linux/ioport.h> #include <linux/bitmap.h> #include <linux/pci.h> #include <asm/opal.h> #include "pci.h" /* * The majority of the complexity in supporting SR-IOV on PowerNV comes from * the need to put the MMIO space for each VF into a separate PE. Internally * the PHB maps MMIO addresses to a specific PE using the "Memory BAR Table". * The MBT historically only applied to the 64bit MMIO window of the PHB * so it's common to see it referred to as the "M64BT". * * An MBT entry stores the mapped range as an <base>,<mask> pair. This forces * the address range that we want to map to be power-of-two sized and aligned. * For conventional PCI devices this isn't really an issue since PCI device BARs * have the same requirement. * * For a SR-IOV BAR things are a little more awkward since size and alignment * are not coupled. The alignment is set based on the per-VF BAR size, but * the total BAR area is: number-of-vfs * per-vf-size. The number of VFs * isn't necessarily a power of two, so neither is the total size. To fix that * we need to finesse (read: hack) the Linux BAR allocator so that it will * allocate the SR-IOV BARs in a way that lets us map them using the MBT. * * The changes to size and alignment that we need to do depend on the "mode" * of MBT entry that we use. We only support SR-IOV on PHB3 (IODA2) and above, * so as a baseline we can assume that we have the following BAR modes * available: * * NB: $PE_COUNT is the number of PEs that the PHB supports. * * a) A segmented BAR that splits the mapped range into $PE_COUNT equally sized * segments. The n'th segment is mapped to the n'th PE. * b) An un-segmented BAR that maps the whole address range to a specific PE. * * * We prefer to use mode a) since it only requires one MBT entry per SR-IOV BAR * For comparison b) requires one entry per-VF per-BAR, or: * (num-vfs * num-sriov-bars) in total. To use a) we need the size of each segment * to equal the size of the per-VF BAR area. So: * * new_size = per-vf-size * number-of-PEs * * The alignment for the SR-IOV BAR also needs to be changed from per-vf-size * to "new_size", calculated above. Implementing this is a convoluted process * which requires several hooks in the PCI core: * * 1. In pcibios_device_add() we call pnv_pci_ioda_fixup_iov(). * * At this point the device has been probed and the device's BARs are sized, * but no resource allocations have been done. The SR-IOV BARs are sized * based on the maximum number of VFs supported by the device and we need * to increase that to new_size. * * 2. Later, when Linux actually assigns resources it tries to make the resource * allocations for each PCI bus as compact as possible. As a part of that it * sorts the BARs on a bus by their required alignment, which is calculated * using pci_resource_alignment(). * * For IOV resources this goes: * pci_resource_alignment() * pci_sriov_resource_alignment() * pcibios_sriov_resource_alignment() * pnv_pci_iov_resource_alignment() * * Our hook overrides the default alignment, equal to the per-vf-size, with * new_size computed above. * * 3. When userspace enables VFs for a device: * * sriov_enable() * pcibios_sriov_enable() * pnv_pcibios_sriov_enable() * * This is where we actually allocate PE numbers for each VF and setup the * MBT mapping for each SR-IOV BAR. In steps 1) and 2) we setup an "arena" * where each MBT segment is equal in size to the VF BAR so we can shift * around the actual SR-IOV BAR location within this arena. We need this * ability because the PE space is shared by all devices on the same PHB. * When using mode a) described above segment 0 in maps to PE#0 which might * be already being used by another device on the PHB. * * As a result we need allocate a contigious range of PE numbers, then shift * the address programmed into the SR-IOV BAR of the PF so that the address * of VF0 matches up with the segment corresponding to the first allocated * PE number. This is handled in pnv_pci_vf_resource_shift(). * * Once all that is done we return to the PCI core which then enables VFs, * scans them and creates pci_devs for each. The init process for a VF is * largely the same as a normal device, but the VF is inserted into the IODA * PE that we allocated for it rather than the PE associated with the bus. * * 4. When userspace disables VFs we unwind the above in * pnv_pcibios_sriov_disable(). Fortunately this is relatively simple since * we don't need to validate anything, just tear down the mappings and * move SR-IOV resource back to its "proper" location. * * That's how mode a) works. In theory mode b) (single PE mapping) is less work * since we can map each individual VF with a separate BAR. However, there's a * few limitations: * * 1) For IODA2 mode b) has a minimum alignment requirement of 32MB. This makes * it only usable for devices with very large per-VF BARs. Such devices are * similar to Big Foot. They definitely exist, but I've never seen one. * * 2) The number of MBT entries that we have is limited. PHB3 and PHB4 only * 16 total and some are needed for. Most SR-IOV capable network cards can support * more than 16 VFs on each port. * * We use b) when using a) would use more than 1/4 of the entire 64 bit MMIO * window of the PHB. * * * * PHB4 (IODA3) added a few new features that would be useful for SR-IOV. It * allowed the MBT to map 32bit MMIO space in addition to 64bit which allows * us to support SR-IOV BARs in the 32bit MMIO window. This is useful since * the Linux BAR allocation will place any BAR marked as non-prefetchable into * the non-prefetchable bridge window, which is 32bit only. It also added two * new modes: * * c) A segmented BAR similar to a), but each segment can be individually * mapped to any PE. This is matches how the 32bit MMIO window worked on * IODA1&2. * * d) A segmented BAR with 8, 64, or 128 segments. This works similarly to a), * but with fewer segments and configurable base PE. * * i.e. The n'th segment maps to the (n + base)'th PE. * * The base PE is also required to be a multiple of the window size. * * Unfortunately, the OPAL API doesn't currently (as of skiboot v6.6) allow us * to exploit any of the IODA3 features. */ static void pnv_pci_ioda_fixup_iov_resources(struct pci_dev *pdev) { struct pnv_phb *phb = pci_bus_to_pnvhb(pdev->bus); struct resource *res; int i; resource_size_t vf_bar_sz; struct pnv_iov_data *iov; int mul; iov = kzalloc(sizeof(*iov), GFP_KERNEL); if (!iov) goto disable_iov; pdev->dev.archdata.iov_data = iov; mul = phb->ioda.total_pe_num; for (i = 0; i < PCI_SRIOV_NUM_BARS; i++) { res = &pdev->resource[i + PCI_IOV_RESOURCES]; if (!res->flags || res->parent) continue; if (!pnv_pci_is_m64_flags(res->flags)) { dev_warn(&pdev->dev, "Don't support SR-IOV with non M64 VF BAR%d: %pR. \n", i, res); goto disable_iov; } vf_bar_sz = pci_iov_resource_size(pdev, i + PCI_IOV_RESOURCES); /* * Generally, one segmented M64 BAR maps one IOV BAR. However, * if a VF BAR is too large we end up wasting a lot of space. * If each VF needs more than 1/4 of the default m64 segment * then each VF BAR should be mapped in single-PE mode to reduce * the amount of space required. This does however limit the * number of VFs we can support. * * The 1/4 limit is arbitrary and can be tweaked. */ if (vf_bar_sz > (phb->ioda.m64_segsize >> 2)) { /* * On PHB3, the minimum size alignment of M64 BAR in * single mode is 32MB. If this VF BAR is smaller than * 32MB, but still too large for a segmented window * then we can't map it and need to disable SR-IOV for * this device. */ if (vf_bar_sz < SZ_32M) { pci_err(pdev, "VF BAR%d: %pR can't be mapped in single PE mode\n", i, res); goto disable_iov; } iov->m64_single_mode[i] = true; continue; } /* * This BAR can be mapped with one segmented window, so adjust * te resource size to accommodate. */ pci_dbg(pdev, " Fixing VF BAR%d: %pR to\n", i, res); res->end = res->start + vf_bar_sz * mul - 1; pci_dbg(pdev, " %pR\n", res); pci_info(pdev, "VF BAR%d: %pR (expanded to %d VFs for PE alignment)", i, res, mul); iov->need_shift = true; } return; disable_iov: /* Save ourselves some MMIO space by disabling the unusable BARs */ for (i = 0; i < PCI_SRIOV_NUM_BARS; i++) { res = &pdev->resource[i + PCI_IOV_RESOURCES]; res->flags = 0; res->end = res->start - 1; } pdev->dev.archdata.iov_data = NULL; kfree(iov); } void pnv_pci_ioda_fixup_iov(struct pci_dev *pdev) { if (pdev->is_virtfn) { struct pnv_ioda_pe *pe = pnv_ioda_get_pe(pdev); /* * VF PEs are single-device PEs so their pdev pointer needs to * be set. The pdev doesn't exist when the PE is allocated (in * (pcibios_sriov_enable()) so we fix it up here. */ pe->pdev = pdev; WARN_ON(!(pe->flags & PNV_IODA_PE_VF)); } else if (pdev->is_physfn) { /* * For PFs adjust their allocated IOV resources to match what * the PHB can support using its M64 BAR table. */ pnv_pci_ioda_fixup_iov_resources(pdev); } } resource_size_t pnv_pci_iov_resource_alignment(struct pci_dev *pdev, int resno) { resource_size_t align = pci_iov_resource_size(pdev, resno); struct pnv_phb *phb = pci_bus_to_pnvhb(pdev->bus); struct pnv_iov_data *iov = pnv_iov_get(pdev); /* * iov can be null if we have an SR-IOV device with IOV BAR that can't * be placed in the m64 space (i.e. The BAR is 32bit or non-prefetch). * In that case we don't allow VFs to be enabled since one of their * BARs would not be placed in the correct PE. */ if (!iov) return align; /* * If we're using single mode then we can just use the native VF BAR * alignment. We validated that it's possible to use a single PE * window above when we did the fixup. */ if (iov->m64_single_mode[resno - PCI_IOV_RESOURCES]) return align; /* * On PowerNV platform, IOV BAR is mapped by M64 BAR to enable the * SR-IOV. While from hardware perspective, the range mapped by M64 * BAR should be size aligned. * * This function returns the total IOV BAR size if M64 BAR is in * Shared PE mode or just VF BAR size if not. * If the M64 BAR is in Single PE mode, return the VF BAR size or * M64 segment size if IOV BAR size is less. */ return phb->ioda.total_pe_num * align; } static int pnv_pci_vf_release_m64(struct pci_dev *pdev, u16 num_vfs) { struct pnv_iov_data *iov; struct pnv_phb *phb; int window_id; phb = pci_bus_to_pnvhb(pdev->bus); iov = pnv_iov_get(pdev); for_each_set_bit(window_id, iov->used_m64_bar_mask, MAX_M64_BARS) { opal_pci_phb_mmio_enable(phb->opal_id, OPAL_M64_WINDOW_TYPE, window_id, 0); clear_bit(window_id, &phb->ioda.m64_bar_alloc); } return 0; } /* * PHB3 and beyond support segmented windows. The window's address range * is subdivided into phb->ioda.total_pe_num segments and there's a 1-1 * mapping between PEs and segments. */ static int64_t pnv_ioda_map_m64_segmented(struct pnv_phb *phb, int window_id, resource_size_t start, resource_size_t size) { int64_t rc; rc = opal_pci_set_phb_mem_window(phb->opal_id, OPAL_M64_WINDOW_TYPE, window_id, start, 0, /* unused */ size); if (rc) goto out; rc = opal_pci_phb_mmio_enable(phb->opal_id, OPAL_M64_WINDOW_TYPE, window_id, OPAL_ENABLE_M64_SPLIT); out: if (rc) pr_err("Failed to map M64 window #%d: %lld\n", window_id, rc); return rc; } static int64_t pnv_ioda_map_m64_single(struct pnv_phb *phb, int pe_num, int window_id, resource_size_t start, resource_size_t size) { int64_t rc; /* * The API for setting up m64 mmio windows seems to have been designed * with P7-IOC in mind. For that chip each M64 BAR (window) had a fixed * split of 8 equally sized segments each of which could individually * assigned to a PE. * * The problem with this is that the API doesn't have any way to * communicate the number of segments we want on a BAR. This wasn't * a problem for p7-ioc since you didn't have a choice, but the * single PE windows added in PHB3 don't map cleanly to this API. * * As a result we've got this slightly awkward process where we * call opal_pci_map_pe_mmio_window() to put the single in single * PE mode, and set the PE for the window before setting the address * bounds. We need to do it this way because the single PE windows * for PHB3 have different alignment requirements on PHB3. */ rc = opal_pci_map_pe_mmio_window(phb->opal_id, pe_num, OPAL_M64_WINDOW_TYPE, window_id, 0); if (rc) goto out; /* * NB: In single PE mode the window needs to be aligned to 32MB */ rc = opal_pci_set_phb_mem_window(phb->opal_id, OPAL_M64_WINDOW_TYPE, window_id, start, 0, /* ignored by FW, m64 is 1-1 */ size); if (rc) goto out; /* * Now actually enable it. We specified the BAR should be in "non-split" * mode so FW will validate that the BAR is in single PE mode. */ rc = opal_pci_phb_mmio_enable(phb->opal_id, OPAL_M64_WINDOW_TYPE, window_id, OPAL_ENABLE_M64_NON_SPLIT); out: if (rc) pr_err("Error mapping single PE BAR\n"); return rc; } static int pnv_pci_alloc_m64_bar(struct pnv_phb *phb, struct pnv_iov_data *iov) { int win; do { win = find_next_zero_bit(&phb->ioda.m64_bar_alloc, phb->ioda.m64_bar_idx + 1, 0); if (win >= phb->ioda.m64_bar_idx + 1) return -1; } while (test_and_set_bit(win, &phb->ioda.m64_bar_alloc)); set_bit(win, iov->used_m64_bar_mask); return win; } static int pnv_pci_vf_assign_m64(struct pci_dev *pdev, u16 num_vfs) { struct pnv_iov_data *iov; struct pnv_phb *phb; int win; struct resource *res; int i, j; int64_t rc; resource_size_t size, start; int base_pe_num; phb = pci_bus_to_pnvhb(pdev->bus); iov = pnv_iov_get(pdev); for (i = 0; i < PCI_SRIOV_NUM_BARS; i++) { res = &pdev->resource[i + PCI_IOV_RESOURCES]; if (!res->flags || !res->parent) continue; /* don't need single mode? map everything in one go! */ if (!iov->m64_single_mode[i]) { win = pnv_pci_alloc_m64_bar(phb, iov); if (win < 0) goto m64_failed; size = resource_size(res); start = res->start; rc = pnv_ioda_map_m64_segmented(phb, win, start, size); if (rc) goto m64_failed; continue; } /* otherwise map each VF with single PE BARs */ size = pci_iov_resource_size(pdev, PCI_IOV_RESOURCES + i); base_pe_num = iov->vf_pe_arr[0].pe_number; for (j = 0; j < num_vfs; j++) { win = pnv_pci_alloc_m64_bar(phb, iov); if (win < 0) goto m64_failed; start = res->start + size * j; rc = pnv_ioda_map_m64_single(phb, win, base_pe_num + j, start, size); if (rc) goto m64_failed; } } return 0; m64_failed: pnv_pci_vf_release_m64(pdev, num_vfs); return -EBUSY; } static void pnv_ioda_release_vf_PE(struct pci_dev *pdev) { struct pnv_phb *phb; struct pnv_ioda_pe *pe, *pe_n; phb = pci_bus_to_pnvhb(pdev->bus); if (!pdev->is_physfn) return; /* FIXME: Use pnv_ioda_release_pe()? */ list_for_each_entry_safe(pe, pe_n, &phb->ioda.pe_list, list) { if (pe->parent_dev != pdev) continue; pnv_pci_ioda2_release_pe_dma(pe); /* Remove from list */ mutex_lock(&phb->ioda.pe_list_mutex); list_del(&pe->list); mutex_unlock(&phb->ioda.pe_list_mutex); pnv_ioda_deconfigure_pe(phb, pe); pnv_ioda_free_pe(pe); } } static int pnv_pci_vf_resource_shift(struct pci_dev *dev, int offset) { struct resource *res, res2; struct pnv_iov_data *iov; resource_size_t size; u16 num_vfs; int i; if (!dev->is_physfn) return -EINVAL; iov = pnv_iov_get(dev); /* * "offset" is in VFs. The M64 windows are sized so that when they * are segmented, each segment is the same size as the IOV BAR. * Each segment is in a separate PE, and the high order bits of the * address are the PE number. Therefore, each VF's BAR is in a * separate PE, and changing the IOV BAR start address changes the * range of PEs the VFs are in. */ num_vfs = iov->num_vfs; for (i = 0; i < PCI_SRIOV_NUM_BARS; i++) { res = &dev->resource[i + PCI_IOV_RESOURCES]; if (!res->flags || !res->parent) continue; if (iov->m64_single_mode[i]) continue; /* * The actual IOV BAR range is determined by the start address * and the actual size for num_vfs VFs BAR. This check is to * make sure that after shifting, the range will not overlap * with another device. */ size = pci_iov_resource_size(dev, i + PCI_IOV_RESOURCES); res2.flags = res->flags; res2.start = res->start + (size * offset); res2.end = res2.start + (size * num_vfs) - 1; if (res2.end > res->end) { dev_err(&dev->dev, "VF BAR%d: %pR would extend past %pR (trying to enable %d VFs shifted by %d)\n", i, &res2, res, num_vfs, offset); return -EBUSY; } } /* * Since M64 BAR shares segments among all possible 256 PEs, * we have to shift the beginning of PF IOV BAR to make it start from * the segment which belongs to the PE number assigned to the first VF. * This creates a "hole" in the /proc/iomem which could be used for * allocating other resources so we reserve this area below and * release when IOV is released. */ for (i = 0; i < PCI_SRIOV_NUM_BARS; i++) { res = &dev->resource[i + PCI_IOV_RESOURCES]; if (!res->flags || !res->parent) continue; if (iov->m64_single_mode[i]) continue; size = pci_iov_resource_size(dev, i + PCI_IOV_RESOURCES); res2 = *res; res->start += size * offset; dev_info(&dev->dev, "VF BAR%d: %pR shifted to %pR (%sabling %d VFs shifted by %d)\n", i, &res2, res, (offset > 0) ? "En" : "Dis", num_vfs, offset); if (offset < 0) { devm_release_resource(&dev->dev, &iov->holes[i]); memset(&iov->holes[i], 0, sizeof(iov->holes[i])); } pci_update_resource(dev, i + PCI_IOV_RESOURCES); if (offset > 0) { iov->holes[i].start = res2.start; iov->holes[i].end = res2.start + size * offset - 1; iov->holes[i].flags = IORESOURCE_BUS; iov->holes[i].name = "pnv_iov_reserved"; devm_request_resource(&dev->dev, res->parent, &iov->holes[i]); } } return 0; } static void pnv_pci_sriov_disable(struct pci_dev *pdev) { u16 num_vfs, base_pe; struct pnv_iov_data *iov; iov = pnv_iov_get(pdev); if (WARN_ON(!iov)) return; num_vfs = iov->num_vfs; base_pe = iov->vf_pe_arr[0].pe_number; /* Release VF PEs */ pnv_ioda_release_vf_PE(pdev); /* Un-shift the IOV BARs if we need to */ if (iov->need_shift) pnv_pci_vf_resource_shift(pdev, -base_pe); /* Release M64 windows */ pnv_pci_vf_release_m64(pdev, num_vfs); } static void pnv_ioda_setup_vf_PE(struct pci_dev *pdev, u16 num_vfs) { struct pnv_phb *phb; struct pnv_ioda_pe *pe; int pe_num; u16 vf_index; struct pnv_iov_data *iov; struct pci_dn *pdn; if (!pdev->is_physfn) return; phb = pci_bus_to_pnvhb(pdev->bus); pdn = pci_get_pdn(pdev); iov = pnv_iov_get(pdev); /* Reserve PE for each VF */ for (vf_index = 0; vf_index < num_vfs; vf_index++) { int vf_devfn = pci_iov_virtfn_devfn(pdev, vf_index); int vf_bus = pci_iov_virtfn_bus(pdev, vf_index); struct pci_dn *vf_pdn; pe = &iov->vf_pe_arr[vf_index]; pe->phb = phb; pe->flags = PNV_IODA_PE_VF; pe->pbus = NULL; pe->parent_dev = pdev; pe->mve_number = -1; pe->rid = (vf_bus << 8) | vf_devfn; pe_num = pe->pe_number; pe_info(pe, "VF %04d:%02d:%02d.%d associated with PE#%x\n", pci_domain_nr(pdev->bus), pdev->bus->number, PCI_SLOT(vf_devfn), PCI_FUNC(vf_devfn), pe_num); if (pnv_ioda_configure_pe(phb, pe)) { /* XXX What do we do here ? */ pnv_ioda_free_pe(pe); pe->pdev = NULL; continue; } /* Put PE to the list */ mutex_lock(&phb->ioda.pe_list_mutex); list_add_tail(&pe->list, &phb->ioda.pe_list); mutex_unlock(&phb->ioda.pe_list_mutex); /* associate this pe to its pdn */ list_for_each_entry(vf_pdn, &pdn->parent->child_list, list) { if (vf_pdn->busno == vf_bus && vf_pdn->devfn == vf_devfn) { vf_pdn->pe_number = pe_num; break; } } pnv_pci_ioda2_setup_dma_pe(phb, pe); } } static int pnv_pci_sriov_enable(struct pci_dev *pdev, u16 num_vfs) { struct pnv_ioda_pe *base_pe; struct pnv_iov_data *iov; struct pnv_phb *phb; int ret; u16 i; phb = pci_bus_to_pnvhb(pdev->bus); iov = pnv_iov_get(pdev); /* * There's a calls to IODA2 PE setup code littered throughout. We could * probably fix that, but we'd still have problems due to the * restriction inherent on IODA1 PHBs. * * NB: We class IODA3 as IODA2 since they're very similar. */ if (phb->type != PNV_PHB_IODA2) { pci_err(pdev, "SR-IOV is not supported on this PHB\n"); return -ENXIO; } if (!iov) { dev_info(&pdev->dev, "don't support this SRIOV device with non 64bit-prefetchable IOV BAR\n"); return -ENOSPC; } /* allocate a contiguous block of PEs for our VFs */ base_pe = pnv_ioda_alloc_pe(phb, num_vfs); if (!base_pe) { pci_err(pdev, "Unable to allocate PEs for %d VFs\n", num_vfs); return -EBUSY; } iov->vf_pe_arr = base_pe; iov->num_vfs = num_vfs; /* Assign M64 window accordingly */ ret = pnv_pci_vf_assign_m64(pdev, num_vfs); if (ret) { dev_info(&pdev->dev, "Not enough M64 window resources\n"); goto m64_failed; } /* * When using one M64 BAR to map one IOV BAR, we need to shift * the IOV BAR according to the PE# allocated to the VFs. * Otherwise, the PE# for the VF will conflict with others. */ if (iov->need_shift) { ret = pnv_pci_vf_resource_shift(pdev, base_pe->pe_number); if (ret) goto shift_failed; } /* Setup VF PEs */ pnv_ioda_setup_vf_PE(pdev, num_vfs); return 0; shift_failed: pnv_pci_vf_release_m64(pdev, num_vfs); m64_failed: for (i = 0; i < num_vfs; i++) pnv_ioda_free_pe(&iov->vf_pe_arr[i]); return ret; } int pnv_pcibios_sriov_disable(struct pci_dev *pdev) { pnv_pci_sriov_disable(pdev); /* Release PCI data */ remove_sriov_vf_pdns(pdev); return 0; } int pnv_pcibios_sriov_enable(struct pci_dev *pdev, u16 num_vfs) { /* Allocate PCI data */ add_sriov_vf_pdns(pdev); return pnv_pci_sriov_enable(pdev, num_vfs); }
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