237 lines
9.1 KiB
Markdown
237 lines
9.1 KiB
Markdown
coreboot 4.13
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================================
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coreboot 4.13 was released on November 20th, 2020.
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Since 4.12 there were 4200 new commits by over 234 developers.
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Of these, about 72 contributed to coreboot for the first time.
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Thank you to all developers who again helped made coreboot better
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than ever, and a big welcome to our new contributors!
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New mainboards
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--------------
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- Acer G43T-AM3
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- AMD Cereme
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- Asus A88XM-E FM2+
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- Biostar TH61-ITX
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- BostenTech GBYT4
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- Clevo L140CU/L141CU
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- Dell OptiPlex 9010
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- Example Min86 (fake board)
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- Google Ambassador
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- Google Asurada
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- Google Berknip
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- Google Boldar
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- Google Boten
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- Google Burnet
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- Google Cerise
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- Google Coachz
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- Google Dalboz
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- Google Dauntless
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- Google Delbin
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- Google Dirinboz
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- Google Dooly
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- Google Drawcia
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- Google Eldrid
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- Google Elemi
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- Google Esche
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- Google Ezkinil
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- Google Faffy
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- Google Fennel
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- Google Genesis
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- Google Hayato
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- Google Lantis
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- Google Lindar
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- Google Madoo
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- Google Magolor
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- Google Metaknight
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- Google Morphius
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- Google Noibat
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- Google Pompom
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- Google Shuboz
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- Google Stern
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- Google Terrador
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- Google Todor
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- Google Trembyle
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- Google Vilboz
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- Google Voema
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- Google Volteer2
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- Google Voxel
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- Google Willow
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- Google Woomax
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- Google Wyvern
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- HP EliteBook 2560p
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- HP EliteBook Folio 9480m
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- HP ProBook 6360b
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- Intel Alderlake-P RVP
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- Kontron COMe-bSL6
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- Lenovo ThinkPad X230s
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- Open Compute Project DeltaLake
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- Prodrive Hermes
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- Purism Librem Mini
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- Purism Librem Mini v2
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- Siemens Chili
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- Supermicro X11SSH-F
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- System76 lemp9
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Removed mainboards
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------------------
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- Google Cheza
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- Google DragonEgg
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- Google Ripto
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- Google Sushi
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- Open Compute Project SonoraPass
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Significant changes
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-------------------
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### Native refcode implementation for Bay Trail
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Bay Trail no longer needs a refcode binary to function properly. The refcode
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was reimplemented as coreboot code, which should be functionally equivalent.
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Thus, coreboot only needs to run the MRC.bin to successfully boot Bay Trail.
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### Unusual config files to build test more code
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There's some new highly-unusual config files, whose only purpose is to coerce
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Jenkins into build-testing several disabled-by-default coreboot config options.
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This prevents them from silently decaying over time because of build failures.
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### Initial support for Intel Trusted eXecution Technology
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coreboot now supports enabling Intel TXT. Though it's not feature-complete yet,
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the code allows successfully launching tboot, a Measured Launch Environment. It
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was tested on Haswell using an Asrock B85M Pro4 mainboard with TPM 2.0 on LPC.
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Though support for other platforms is still not ready, it is being worked on.
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The Haswell MRC.bin needs to be patched so as to enable DPR. Given that the MRC
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binary cannot be redistributed, the best long-term solution is to replace it.
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### Hidden PCI devices
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This new functionality takes advantage of the existing 'hidden' keyword in the
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devicetree. Since no existing boards were using the keyword, its usage was
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repurposed to make dealing with some unique PCI devices easier. The particular
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case here is Intel's PMC (Power Management Controller). During the FSP-S run,
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the PMC device is made hidden, meaning that its config space looks as if there
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is no device there (Vendor ID reads as 0xFFFF_FFFF). However, the device does
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have fixed resources, both MMIO and I/O. These were previously recorded in
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different places (MMIO was typically an SA fixed resource, and I/O was treated
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as an LPC resource). With this change, when a device in the tree is marked as
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'hidden', it is not probed (`pci_probe_dev()`) but rather assumed to exist so
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that its resources can be placed in a more natural location. This also adds the
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ability for the device to participate in SSDT generation.
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### Tools for generating SPDs for LP4x memory on TGL and JSL
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A set of new tools `gen_spd.go` and `gen_part_id.go` are added to automate the
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process of generating SPDs for LP4x memory and assigning hardware strap IDs for
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memory parts used on TGL and JSL based boards. The SPD data obtained from memory
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part vendors has to be massaged to format it correctly as per JEDEC and Intel MRC
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expectations. These tools take a list of memory parts describing their physical
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attributes as per their datasheet and convert those attributes into SPD files for
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the platforms. More details about the tools are added in
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[README.md](https://review.coreboot.org/plugins/gitiles/coreboot/+/refs/heads/master/util/spd_tools/intel/lp4x/README.md).
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### New version of SMM loader
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A new version of the SMM loader which accommodates platforms with over 32
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CPU threads. The existing version of SMM loader uses a 64K code/data
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segment and only a limited number of CPU threads can fit into one segment
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(because of save state, STM, other features, etc). This loader extends beyond
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the 64K segment to accommodate additional CPUs and in theory allows as many
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CPU threads as possible limited only by SMRAM space and not by 64K. By default
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this loader version is disabled. Please see cpu/x86/Kconfig for more info.
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### Address Sanitizer
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coreboot now has an in-built Address Sanitizer, a runtime memory debugger
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designed to find out-of-bounds access and use-after-scope bugs. It is made
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available on all x86 platforms in ramstage and on QEMU i440fx, Intel Apollo
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Lake, and Haswell in romstage. Further, it can be enabled in romstage on other
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x86 platforms as well. Refer [ASan documentation](../technotes/asan.md) for
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more info.
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### Initial support for x86_64
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The x86_64 code support has been revived and enabled for QEMU. While it started
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as PoC and the only supported platform is an emulator, there's interest in
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enabling additional platforms. It would allow to access more than 4GiB of memory
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at runtime and possibly brings optimised code for faster execution times.
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It still needs changes in assembly, fixed integer to pointer conversions in C,
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wrappers for blobs, support for running Option ROMs, among other things.
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### Preparations to minimize enabling PCI bus mastering
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For security reasons, bus mastering should be enabled as late as possible. In
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coreboot, it's usually not necessary and payloads should only enable it for
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devices they use. Since not all payloads enable bus mastering properly yet,
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some Kconfig options were added as an intermediate step to give some sort of
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"backwards compatibility", which allow enabling or disabling bus mastering by
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groups.
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Currently available groups are:
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* PCI bridges
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* Any devices
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For now, "Any devices" is enabled by default to keep the traditional behaviour,
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which also includes all other options. This is currently necessary, for instance,
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for libpayload-based payloads as the drivers don't enable bus mastering for PCI
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bridges.
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Exceptional cases, that may still need early bus master enabling in the future,
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should get their own per-reason Kconfig option. Ideally before the next release.
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### Early runtime configurability of the console log level
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Traditionally, we didn't allow the log level of the `romstage` console
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to be changed at runtime (e.g. via `get_option()`). It turned out that
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the technical constraints for this (no global variables in `romstage`)
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vanished long ago, though. The new behaviour is to query `get_option()`
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now from the second stage that uses the console on. In other words, if
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the `bootblock` already enables the console, the `romstage` log level
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can be changed via `get_option()`. Keeping the log level of the first
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console static ensures that we can see console output even if there's
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a bug in the more involved code to query options.
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### Resource allocator v4
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A new revision of resource allocator v4 is now added to coreboot that supports
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mutiple ranges for allocating resources. Unlike the previous allocator (v3), it does
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not use the topmost available window for allocation. Instead, it uses the first
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window within the address space that is available and satisfies the resource request.
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This allows utilization of the entire available address space and also allows
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allocation above the 4G boundary. The old resource allocator v3 is still retained for
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some AMD platforms that do not conform to the requirements of the allocator.
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Deprecations
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------------
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### PCI bus master configuration options
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In order to minimize the usage of PCI bus mastering, the options we introduced in
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this release will be dropped in a future release again. For more details, please
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see [Preparations to minimize enabling PCI bus mastering](#preparations-to-minimize-enabling-pci-bus-mastering-in-coreboot).
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### Resource allocator v3
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Resource allocator v3 is retained in coreboot tree because the following platforms
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do not conform to the requirements of the resource allocation i.e. not all the fixed
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resources of the platform are provided during the `read_resources()` operation:
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* northbridge/amd/pi/00630F01
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* northbridge/amd/pi/00730F01
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* northbridge/amd/pi/00660F01
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* northbridge/amd/agesa/family14
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* northbridge/amd/agesa/family15tn
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* northbridge/amd/agesa/family16kb
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In order to have a single unified allocator in coreboot, this notice is being added
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to ensure that the platforms listed above are fixed before the next release. If there
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is interest in maintaining support for these platforms beyond the next release,
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please ensure that the platforms are fixed to conform to the expectations of resource
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allocation.
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