- 26 Jul, 2020 40 commits
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Athira Rajeev authored
Initialize Monitor Mode Control Register 3 (MMCR3) SPR which is new in power10. For PowerISA v3.1, BHRB disable is controlled via Monitor Mode Control Register A (MMCRA) bit, namely "BHRB Recording Disable (BHRBRD)". This patch also initializes MMCRA BHRBRD to disable BHRB feature at boot for power10. Reported-by:
kernel test robot <lkp@intel.com> Signed-off-by:
Athira Rajeev <atrajeev@linux.vnet.ibm.com> Reviewed-by:
Jordan Niethe <jniethe5@gmail.com> Signed-off-by:
Michael Ellerman <mpe@ellerman.id.au> Link: https://lore.kernel.org/r/1595489557-2047-1-git-send-email-atrajeev@linux.vnet.ibm.com
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Oliver O'Halloran authored
Previously iov->vfs_expanded was used for two purposes. 1) To work out how much we need to multiple the per-VF BAR size to figure out the total space required for the IOV BAR. 2) To indicate that IOV is not usable with this device (vfs_expanded == 0). We don't really need the field for either since the multiple in 1) is always the number PEs supported by the PHB. Similarly, we don't really need it in 2) either since the IOV data field will be NULL if we can't use IOV with the device. Signed-off-by:
Oliver O'Halloran <oohall@gmail.com> Signed-off-by:
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Oliver O'Halloran authored
Using single PE BARs to map an SR-IOV BAR is really a choice about what strategy to use when mapping a BAR. It doesn't make much sense for this to be a global setting since a device might have one large BAR which needs to be mapped with single PE windows and another smaller BAR that can be mapped with a regular segmented window. Make the segmented vs single decision a per-BAR setting and clean up the logic that decides which mode to use. Signed-off-by:
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Oliver O'Halloran authored
Split up the logic so that we have one branch that handles setting up a segmented window and another that handles setting up single PE windows for each VF. Signed-off-by:
Alexey Kardashevskiy <aik@ozlabs.ru> Signed-off-by:
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Oliver O'Halloran authored
I want to refactor the loop this code is currently inside of. Hoist it on out. Signed-off-by:
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Oliver O'Halloran authored
Remove the IODA2 PHB checks. We already assume IODA2 in several places so there's not much point in wrapping most of the setup and teardown process in an if block. Signed-off-by:
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Oliver O'Halloran authored
Currently the iov->pe_num_map[] does one of two things depending on whether single PE mode is being used or not. When it is, this contains an array which maps a vf_index to the corresponding PE number. When single PE mode is not being used this contains a scalar which is the base PE for the set of enabled VFs (for for VFn is base + n). The array was necessary because when calling pnv_ioda_alloc_pe() there is no guarantee that the allocated PEs would be contigious. We can now allocate contigious blocks of PEs so this is no longer an issue. This allows us to drop the if (single_mode) {} .. else {} block scattered through the SR-IOV code which is a nice clean up. This also fixes a bug in pnv_pci_sriov_disable() which is the non-atomic bitmap_clear() to manipulate the PE allocation map. Other users of the map assume it will be accessed with atomic ops. Signed-off-by: -
Oliver O'Halloran authored
Rework the PE allocation logic to allow allocating blocks of PEs rather than individually. We'll use this to allocate contigious blocks of PEs for the SR-IOVs. This patch also adds code to pnv_ioda_alloc_pe() and pnv_ioda_reserve_pe() to use the existing, but unused, phb->pe_alloc_mutex. Currently these functions use atomic bit ops to release a currently allocated PE number. However, the pnv_ioda_alloc_pe() wants to have exclusive access to the bit map while scanning for hole large enough to accomodate the allocation size. Signed-off-by:
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Oliver O'Halloran authored
The sequence required to use the single PE BAR mode is kinda janky and requires a little explanation. The API was designed with P7-IOC style windows where the setup process is something like: 1. Configure the window start / end address 2. Enable the window 3. Map the segments of each window to the PE For Single PE BARs the process is: 1. Set the PE for segment zero on a disabled window 2. Set the range 3. Enable the window Move the OPAL calls into their own helper functions where the quirks can be contained. Signed-off-by:
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Oliver O'Halloran authored
No need for the multi-dimensional arrays, just use a bitmap. Signed-off-by:
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Oliver O'Halloran authored
This prevents SR-IOV being used by making the SR-IOV BAR resources unallocatable. Rename it to reflect what it actually does. Signed-off-by:
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Oliver O'Halloran authored
SR-IOV support on PowerNV is a byzantine maze of hooks. I have no idea how anyone is supposed to know how it works except through a lot of stuffering. Write up some docs about the overall story to help out the next sucker^Wperson who needs to tinker with it. Signed-off-by:
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Oliver O'Halloran authored
pci-ioda.c is getting a bit unwieldly due to the amount of stuff jammed in there. The SR-IOV support can be extracted easily enough and is mostly standalone, so move it into a separate file. This patch also moves the PowerNV SR-IOV specific fields from pci_dn and moves them into a platform specific structure. I'm not sure how they ended up in there in the first place, but leaking platform specifics into common code has proven to be a terrible idea so far so lets stop doing that. Signed-off-by:
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Oliver O'Halloran authored
We pre-configure the m64 window for IODA1 as a 1-1 segment-PE mapping, similar to PHB3. Currently the actual mapping of segments occurs in pnv_ioda_pick_m64_pe(), but we can move it into pnv_ioda1_init_m64() and drop the IODA1 specific code paths in the PE setup / teardown. Signed-off-by:
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Oliver O'Halloran authored
There's an optimisation in the PE setup which skips performing DMA setup for a PE if we only have bridges in a PE. The assumption being that only "real" devices will DMA to system memory, which is probably fair. However, if we start off with only bridge devices in a PE then add a non-bridge device the new device won't be able to use DMA because we never configured it. Fix this (admittedly pretty weird) edge case by tracking whether we've done the DMA setup for the PE or not. If a non-bridge device is added to the PE (via rescan or hotplug, or whatever) we can set up DMA on demand. This also means the only remaining user of the old "DMA Weight" code is the IODA1 DMA setup code that it was originally added for, which is good. Signed-off-by:
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Oliver O'Halloran authored
Currently we have these two functions: pnv_pci_ioda2_release_dma_pe(), and pnv_pci_ioda2_release_pe_dma() The first is used when tearing down VF PEs and the other is used for normal devices. There's very little difference between the two though. The latter (non-VF) will skip a call to pnv_pci_ioda2_unset_window() unless CONFIG_IOMMU_API=y is set. There's no real point in doing this so fold the two together. Signed-off-by:
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Oliver O'Halloran authored
Add a helper to go from a pci_bus structure to the pnv_phb that hosts that bus. There's a lot of instances of the following pattern: struct pci_controller *hose = pci_bus_to_host(pdev->bus); struct pnv_phb *phb = hose->private_data; Without any other uses of the pci_controller inside the function. This is hard to read since it requires you to memorise the contents of the private data fields and kind of error prone since it involves blindly assigning a void pointer. Add a helper to make it more concise and explicit. Signed-off-by:
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Oliver O'Halloran authored
The EEH core has a concept of a "PE tree" to support PowerNV. The PE tree follows the PCI bus structures because a reset asserted on an upstream bridge will be propagated to the downstream bridges. On pseries there's a 1-1 correspondence between what the guest sees are a PHB and a PE so the "tree" is really just a single node. Current the EEH core is reponsible for setting up this PE tree which it does by traversing the pci_dn tree. The structure of the pci_dn tree matches the bus tree on PowerNV which leads to the PE tree being "correct" this setup method doesn't make a whole lot of sense and it's actively confusing for the pseries case where it doesn't really do anything. We want to remove the dependence on pci_dn anyway so this patch move choosing where to insert a new PE into the platform code rather than being part of the generic EEH code. For PowerNV this simplifies the tree building logic and removes the use of pci_dn. For pseries we keep the existing logic. I'm not really convinced it does anything due to the 1-1 PE-to-PHB correspondence so every device under that PHB should be in the same PE, but I'd rather not remove it entirely until we've had a chance to look at it more deeply. Signed-off-by:
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Oliver O'Halloran authored
This is mostly just to make the subsequent diffs less noisy. No functional changes. One thing that needs calling out is the removal of the "config_addr" variable and replacing it with edev->bdfn. The contents of edev->bdfn are the same, however it's worth pointing out that what RTAS calls a "config_addr" isn't the same as the bdfn. The config_addr is supposed to be: <bus><devfn><reg> with each field being an 8 bit number. Various parts of the EEH code use BDFN and "config_addr" as interchangeable quantities even though they aren't really. Signed-off-by:
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Oliver O'Halloran authored
The naming of eeh_{add_to|remove_from}_parent_pe() doesn't really reflect what they actually do. If the PE referred to be edev->pe_config_addr already exists under that PHB then the edev is added to that PE. However, if the PE doesn't exist the a new one is created for the edev. The bulk of the implementation of eeh_add_to_parent_pe() covers that second case. Similarly, most of eeh_remove_from_parent_pe() is determining when it's safe to delete a PE. Signed-off-by: -
Oliver O'Halloran authored
The edev->class_code field is never referenced anywhere except for the platform specific probe functions. The same information is available in the pci_dev for PowerNV and in the pci_dn on pseries so we can remove the field. Signed-off-by:
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Oliver O'Halloran authored
Retrieve the domain, bus, device, and function numbers from the edev. Signed-off-by:
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Oliver O'Halloran authored
Mechanical conversion of the eeh_ops interfaces to use eeh_dev to reference a specific device rather than pci_dn. No functional changes. Signed-off-by:
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Oliver O'Halloran authored
Mechanical conversion of the eeh_ops interfaces to use eeh_dev to reference a specific device rather than pci_dn. No functional changes. Signed-off-by:
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Oliver O'Halloran authored
Mechanical conversion of the eeh_ops interfaces to use eeh_dev to reference a specific device rather than pci_dn. No functional changes. Signed-off-by:
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Oliver O'Halloran authored
There's a bunch of strange things about this code. First up is that none of the fields being written to are functional for a VF. The SR-IOV specification lists then as "Reserved, but OS should preserve" so writing new values to them doesn't do anything and is clearly wrong from a correctness perspective. However, since VFs are designed to be managed by the OS there is an argument to be made that we should be saving and restoring some parts of config space. We already sort of do that by saving the first 64 bytes of config space in the eeh_dev (see eeh_dev->config_space[]). This is inadequate since it doesn't even consider saving and restoring the PCI capability structures. However, this is a problem with EEH in general and that needs to be fixed for non-VF devices too. There's no real reason to keep around this around so delete it. Signed-off-by:
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Oliver O'Halloran authored
This is used in precisely one place which is in pseries specific platform code. There's no need to have the callback in eeh_ops since the platform chooses the EEH PE addresses anyway. The PowerNV implementation has always been a stub too so remove it. Signed-off-by:
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Oliver O'Halloran authored
The pci_dn->pe_number field is mainly used to track the IODA PE number of a device on PowerNV. At some point it grew a user in the pseries SR-IOV support which muddies the waters a bit, so remove it. Signed-off-by:
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Oliver O'Halloran authored
Drivers that do not support the PCI error handling callbacks are handled by tearing down the device and re-probing them. If the device being removed is a virtual function then we need to know the VF index so it can be removed using the pci_iov_{add|remove}_virtfn() API. Currently this is handled by looking up the pci_dn, and using the vf_index that was stashed there when the pci_dn for the VF was created in pcibios_sriov_enable(). We would like to eliminate the use of pci_dn outside of pseries though so we need to provide the generic EEH code with some other way to find the vf_index. The easiest thing to do here is move the vf_index field out of pci_dn and into eeh_dev. Currently pci_dn and eeh_dev are allocated and initialized together so this is a fairly minimal change in preparation for splitting pci_dn and eeh_dev in the future. Signed-off-by: -
Oliver O'Halloran authored
The only thing in this file is eeh_dev_init() which is allocates and initialises an eeh_dev based on a pci_dn. This is only ever called from pci_dn.c so move it into there and remove the file. Signed-off-by:
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Oliver O'Halloran authored
This function is a one line wrapper around eeh_phb_pe_create() and despite the name it doesn't create any eeh_dev structures. Replace it with direct calls to eeh_phb_pe_create() since that does what it says on the tin and removes a layer of indirection. Signed-off-by:
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Ravi Bangoria authored
Power10 has removed 512 bytes boundary from match criteria i.e. the watch range can cross 512 bytes boundary. Note: ISA 3.1 Book III 9.4 match criteria includes 512 byte limit but that is a documentation mistake and hopefully will be fixed in the next version of ISA. Though, ISA 3.1 change log mentions about removal of 512B boundary: Multiple DEAW: Added a second Data Address Watchpoint. [H]DAR is set to the first byte of overlap. 512B boundary is removed. Signed-off-by:
Ravi Bangoria <ravi.bangoria@linux.ibm.com> Signed-off-by:
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Ravi Bangoria authored
So far Book3S Powerpc supported only one watchpoint. Power10 is introducing 2nd DAWR. Enable 2nd DAWR support for Power10. Availability of 2nd DAWR will depend on CPU_FTR_DAWR1. Signed-off-by:
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Ravi Bangoria authored
2nd DAWR can be set/unset using H_SET_MODE hcall with resource value 5. Enable powervm guest support with that. This has no effect on kvm guest because kvm will return error if guest does hcall with resource value 5. Signed-off-by:
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Ravi Bangoria authored
Current H_SET_MODE hcall macro name for setting/resetting DAWR0 is H_SET_MODE_RESOURCE_SET_DAWR. Add suffix 0 to macro name as well. Signed-off-by:
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Ravi Bangoria authored
As per the PAPR, bit 0 of byte 64 in pa-features property indicates availability of 2nd DAWR registers. i.e. If this bit is set, 2nd DAWR is present, otherwise not. Host generally uses "cpu-features", which masks "pa-features". But "cpu-features" are still not used for guests and thus this change is mostly applicable for guests only. Signed-off-by:
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Ravi Bangoria authored
Add new device-tree feature for 2nd DAWR. If this feature is present, 2nd DAWR is supported, otherwise not. Signed-off-by:
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Ravi Bangoria authored
CPU_FTR_DAWR is by default enabled for host via CPU_FTRS_DT_CPU_BASE (controlled by CONFIG_PPC_DT_CPU_FTRS). But cpu-features device-tree node is not PAPR compatible and thus not yet used by kvm or pHyp guests. Enable watchpoint functionality on power10 guest (both kvm and powervm) by adding CPU_FTR_DAWR to CPU_FTRS_POWER10. Note that this change does not enable 2nd DAWR support. Signed-off-by:
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Ravi Bangoria authored
'ea' returned by analyse_instr() needs to be aligned down to cache block size for CACHEOP instructions. analyse_instr() does not set size for CACHEOP, thus size also needs to be calculated manually. Fixes: 27985b2a ("powerpc/watchpoint: Don't ignore extraneous exceptions blindly") Fixes: 74c68810 ("powerpc/watchpoint: Prepare handler to handle more than one watchpoint") Signed-off-by:
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Ravi Bangoria authored
Pedro Miraglia Franco de Carvalho noticed that on p8/p9, DAR value is inconsistent with different type of load/store. Like for byte,word etc. load/stores, DAR is set to the address of the first byte of overlap between watch range and real access. But for quadword load/ store it's sometime set to the address of the first byte of real access whereas sometime set to the address of the first byte of overlap. This issue has been fixed in p10. In p10(ISA 3.1), DAR is always set to the address of the first byte of overlap. Commit 27985b2a ("powerpc/watchpoint: Don't ignore extraneous exceptions blindly") wrongly assumes that DAR is set to the address of the first byte of overlap for all load/stores on p8/p9 as well. Fix that. With the fix, we now rely on 'ea' provided by analyse_instr(). If analyse_instr() fails, generate event unconditionally on p8/p9, and on p10 generate event only if DAR is within a DAWR range. Note: 8xx is not affected. Fixes: 27985b2a ("powerpc/watchpoint: Don't ignore extraneous exceptions blindly") Fixes: 74c68810 ("powerpc/watchpoint: Prepare handler to handle more than one watchpoint") Reported-by:
Pedro Miraglia Franco de Carvalho <pedromfc@br.ibm.com> Signed-off-by:
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