Coreboot Options: Difference between revisions

Append an extra string to the end of the coreboot version.

This can be useful if, for instance, you want to append the respective board's hostname or some other identifying string to the coreboot version number, so that you can easily distinguish boot logs of different boards from each other.

Select the prefix to all files put into the image. It's "fallback" by default, "normal" is a common alternative.

This option allows you to select the compiler used for building coreboot. You must build the coreboot crosscompiler for the board that you have selected.

To build all the GCC crosscompilers (takes a LONG time), run: make crossgcc

For help on individual architectures, run the command: make help_toolchain

Use the GNU Compiler Collection (GCC) to build coreboot.

For details see http://gcc.gnu.org.

Use LLVM/clang to build coreboot. To use this, you must build the coreboot version of the clang compiler. Run the command make clang Note that this option is not currently working correctly and should really only be selected if you're trying to work on getting clang operational.

For details see http://clang.llvm.org.

Many toolchains break when building coreboot since it uses quite unusual linker features. Unless developers explicitely request it, we'll have to assume that they use their distro compiler by mistake. Make sure that using patched compilers is a conscious decision.

Enables the use of ccache for faster builds.

Requires the ccache utility in your system $PATH.

For details see https://ccache.samba.org.

Enable this option if you are working on the flashmap descriptor parser and made changes to fmd_scanner.l or fmd_parser.y.

Otherwise, say N to use the provided pregenerated scanner/parser.

Enable this option if you are working on the sconfig device tree parser or bincfg and made changes to the .l or .y files.

Otherwise, say N to use the provided pregenerated scanner/parser.

Enable this option if coreboot shall read options from the "CMOS" NVRAM instead of using hard-coded values.

Enable this option to reset "CMOS" NVRAM values to default on every boot. Use this if you want the NVRAM configuration to never be modified from its default values.

Compress ramstage to save memory in the flash image. Note that decompression might slow down booting if the boot flash is connected through a slow link (i.e. SPI).

Compress romstage and (if it exists) verstage with LZ4 to save flash space and speed up boot, since the time for reading the image from SPI (and in the vboot case verifying it) is usually much greater than the time spent decompressing. Doesn't work for XIP stages (assume all ARCH_X86 for now) for obvious reasons.

This option can be used to compress the bootblock with LZ4 and attach a small self-decompression stub to its front. This can drastically reduce boot time on platforms where the bootblock is loaded over a very slow connection and bootblock size trumps all other factors for speed. Since this using this option usually requires changes to the SoC memlayout and possibly extra support code, it should not be user-selectable. (There's no real point in offering this to the user anyway... if it works and saves boot time, you would always want it.)

Include the .config file that was used to compile coreboot in the (CBFS) ROM image. This is useful if you want to know which options were used to build a specific coreboot.rom image.

Saying Y here will increase the image size by 2-3KB.

You can use the following command to easily list the options:

grep -a CONFIG_ coreboot.rom

Alternatively, you can also use cbfstool to print the image contents (including the raw 'config' item we're looking for).

Example:

$ cbfstool coreboot.rom print coreboot.rom: 4096 kB, bootblocksize 1008, romsize 4194304, offset 0x0 Alignment: 64 bytes

Name Offset Type Size cmos_layout.bin 0x0 cmos layout 1159 fallback/romstage 0x4c0 stage 339756 fallback/ramstage 0x53440 stage 186664 fallback/payload 0x80dc0 payload 51526 config 0x8d740 raw 3324 (empty) 0x8e480 null 3610440

Make coreboot create a table of timer-ID/timer-value pairs to allow measuring time spent at different phases of the boot process.

Print the timestamps to the debug console if enabled at level spew.

This draws in the blobs repository, which contains binary files that might be required for some chipsets or boards. This flag ensures that a "Free" option remains available for users.

Add code coverage support for coreboot. This will store code coverage information in CBMEM for extraction from user space. If unsure, say N.

Instrument the code with checks for undefined behavior. If unsure, say N because it adds a small performance penalty and may abort on code that happens to work in spite of the UB.

The reloctable ramstage support allows for the ramstage to be built as a relocatable module. The stage loader can identify a place out of the OS way so that copying memory is unnecessary during an S3 wake. When selecting this option the romstage is responsible for determing a stack location to use for loading the ramstage.

The relocated ramstage is saved in an area specified by the by the board and/or chipset.

If this option is enabled, no new coreboot.rom file is created. Instead it is expected that there already is a suitable file for further processing. The bootblock will not be modified.

If unsure, select 'N'

Select this option if you have a bootsplash image that you would like to add to your ROM.

This will only add the image to the ROM. To actually run it check options under 'Display' section.

The path and filename of the file to use as graphical bootsplash screen. The file format has to be jpg.

The Mohon Peak board uses COM2 (2f8) for the serial console.

The Avoton/Rangeley chip does not allow devices to write into the 0xe000 segment. This means that USB/SATA devices will not work in SeaBIOS unless we put the SeaBIOS buffer area down in the 0x9000 segment.

Select this option to enable Memory Down function.

Location of SPD binary for memory down function.

The Little Plains board uses COM2 (2f8) for the serial console.

The Avoton/Rangeley chip does not allow devices to write into the 0xe000 segment. This means that USB/SATA devices will not work in SeaBIOS unless we put the SeaBIOS buffer area down in the 0x9000 segment.

The coreboot binary will configure only one generation of the Galileo board since coreboot can not determine the board generation at runtime. Select which generation of the Galileo that coreboot should initialize.

Use FSP 1_1 binary

Use FSP 2.0 binary

Use the debug version of FSP

Use the release version of FSP

FSP 1.1 implemented as subroutines, no EDK-II cores

FSP 1.1 implemented using SEC and PEI core

FSP 2.0 implemented as subroutines, no EDK-II cores

FSP 2.0 implemented using SEC and PEI core

Turn on debug support to display HOBS, MTRRS, SMM_MEMORY_MAP, UPD_DATA also turn on FSP 2.0 debug support for ESRAM_LAYOUT, FSP_CALLS_AND_STATUS, FSP_HEADER, POSTCAR_CONSOLE and VERIFY_HOBS or FSP 1.1 DISPLAY_FSP_ENTRY_POINTS

Perform a verified boot using the TPM on the Crypto Shield board.

I2C address of the TPM chip on the Crypto Shield board.

The build system creates a default FMAP from ROM_SIZE and CBFS_SIZE, but in some cases more complex setups are required.

When an FMD descriptionn file is specified, the build system uses it instead of creating a default FMAP file.

This option allows you to select the on board EC to use. Select whether the board has Intel EC or Chrome EC

Serial output requires soldering to the testpad next to NCT5577D pin 18 (txd) and gnd.

The C0 version of the video bios gets computed from this name so that they can both be added. Only the correct one for the system will be run.

The VGA_BIOS_ID for the C0 version of the video bios is hardcoded in soc/intel/braswell/Makefile.inc as 8086,22b1

To run coreboot in spike:

• run "make" as usual
• util/riscv/make-spike-elf.sh build/coreboot.{rom,elf}
• spike -m1024 build/coreboot.elf

Select your preferenced DDR3 clock setting.

Note: This option changes the total power consumption.

If unsure, use DDR3-1333.

Select your preferred DDR3 clock setting.

Note: This option changes the total power consumption.

If unsure, use DDR3-1066.

The PCI Express slot at J120 can be configured as an additional DisplayPort connector using an adapter card from AMD or as a normal PCI Express (x4) slot.

By default, the connector is configured as a PCI Express (x4) slot.

Select this option to enable the slot for use with one of AMD's passive graphics port expander cards (only available from AMD).

Which boot media to configure the BCT for.

Configure the BCT for booting from SPI.

Configure the BCT for booting from eMMC.

Which SPI bus the boot media is connected to.

When enabled displays the memory configuration data.

The C0 version of the video bios gets computed from this name so that they can both be added. Only the correct one for the system will be run.

The VGA_BIOS_ID for the C0 version of the video bios is hardcoded in soc/intel/braswell/Makefile.inc as 8086,22b1

The build system creates a default FMAP from ROM_SIZE and CBFS_SIZE, but in some cases more complex setups are required. When an fmd is specified, it overrides the default format.

Which boot media to configure the BCT for.

Configure the BCT for booting from SPI.

Configure the BCT for booting from eMMC.

Which SPI bus the boot media is connected to.

Which boot media to configure the BCT for.

Configure the BCT for booting from SPI.

Configure the BCT for booting from eMMC.

Which SPI bus the boot media is connected to.

Which boot media to configure the BCT for.

Configure the BCT for booting from SPI.

Configure the BCT for booting from eMMC.

Which SPI bus the boot media is connected to.

Which boot media to configure the BCT for.

Configure the BCT for booting from SPI.

Configure the BCT for booting from eMMC.

Which SPI bus the boot media is connected to.

The Mohon Peak board uses COM2 (2f8) for the serial console.

The Avoton/Rangeley chip does not allow devices to write into the 0xe000 segment. This means that USB/SATA devices will not work in SeaBIOS unless we put the SeaBIOS buffer area down in the 0x9000 segment.

Set DRR3 memory voltage to 1.35V

Set DRR3 memory voltage to 1.50V

Set DRR3 memory voltage to 1.65V

Location of BMC SERIAL information.

This platform does not have any way to see POST codes so disable them by default.

Default PS/2 Keyboard to enabled on this board.

This platform does not have any way to get standard serial output so disable it by default.

This platform does not have any way to see POST codes so disable them by default.

If selected, both on-board serial ports will operate in RS485 mode instead of RS232.

If selected, the on-board SSD will act as IDE Slave instead of Master.

Look on the bottom side for a number like 406-0001-30. The last 2 digits state the PCB revision (3.0 in this example). For 2.0 or older boards choose Y, for 3.0 and newer say N.

Old revision boards need a jumper shorting the power button to power on automatically. You may enable the button only after this jumper has been removed. New revision boards are not restricted in this way, and always have the power button enabled.

If selected, both on-board serial ports will operate in RS485 mode instead of RS232.

If selected, the first two on-board serial ports will operate in RS485 mode instead of RS232.

If selected, the on-board Compact Flash card socket will act as IDE Slave instead of Master.

If selected, both on-board serial ports will operate in RS485 mode instead of RS232.

Select the size of the ROM chip you intend to flash coreboot on.

The build system will take care of creating a coreboot.rom file of the matching size.

Choose this option if you have a 64 KB ROM chip.

Choose this option if you have a 128 KB ROM chip.

Choose this option if you have a 256 KB ROM chip.

Choose this option if you have a 512 KB ROM chip.

Choose this option if you have a 1024 KB (1 MB) ROM chip.

Choose this option if you have a 2048 KB (2 MB) ROM chip.

Choose this option if you have a 4096 KB (4 MB) ROM chip.

Choose this option if you have a 8192 KB (8 MB) ROM chip.

Choose this option if you have a 10240 KB (10 MB) ROM chip.

Choose this option if you have a 12288 KB (12 MB) ROM chip.

Choose this option if you have a 16384 KB (16 MB) ROM chip.

Choose this option if you have a 32768 KB (32 MB) ROM chip.

Choose this option if you have a 65536 KB (64 MB) ROM chip.

The selected mainboard can optionally have the power button tied to ground with a jumper so that the button appears to be constantly depressed. If this option is enabled and the jumper is installed then the board will turn on, but turn off again after a short timeout, usually 4 seconds.

Select Y here if you have removed the jumper and want to use an actual power button. Select N if you have the jumper installed.

This symbol allows mainboards to select a different file under their mainboard directory for the devicetree.cb file. This allows the board variants that need different devicetrees to be in the same directory.

Examples: "devicetree.variant.cb" "variant/devicetree.cb"

This is the part of the ROM actually managed by CBFS, located at the end of the ROM (passed through cbfstool -o) on x86 and at at the start of the ROM (passed through cbfstool -s) everywhere else. It defaults to span the whole ROM on all but Intel systems that use an Intel Firmware Descriptor. It can be overridden to make coreboot live alongside other components like ChromeOS's vboot/FMAP or Intel's IFD / ME / TXE binaries.

The build system creates a default FMAP from ROM_SIZE and CBFS_SIZE, but in some cases more complex setups are required. When an fmd is specified, it overrides the default format.

If this option is selected, every file in cbfs which has a constraint regarding position or alignment will get an additional file attribute which describes this constraint.

Initialize dsi display

Initialize dp display

Serial console on UART A.

Serial console on UART B.

Serial console on UART C.

Serial console on UART D.

Serial console on UART E.

Map the UART names to the respective MMIO addres.

Use during Foster LPDDR4 bringup.

Size of Trust Zone area in MiB to reserve in memory map.

Maximum size of Translation Table Buffer in MiB.

Maximum size of resident EL3 components in MiB including BL31 and Secure OS.

Select this option to add emc training firmware

The filename of the mtc firmware

Path to directory where MTC firmware file is located.

The DRAM location where MTC firmware to be loaded in. This location needs to be consistent with the location defined in tegra_mtc.ld

Intel Apollolake support

Intel GLK support

TPM part is conntected on Fast SPI interface, but the LPC MMIO TPM transactions are decoded and serialized over the SPI interface.

This option allows you to select MMIO Base Address of sideband bus.

The size of the cache-as-ram region required during bootblock and/or romstage.

The amount of anticipated stack usage in CAR by bootblock and other stages.

The base address (in CAR) where romstage should be linked

The base address (in CAR) where verstage should be linked

The address FSP-M will be relocated to during build time

Write the contents from a file into the logical boot partition 2 region defined by LBP2_FMAP_NAME.

Name of FMAP region to write logical boot partition 2 data.

Name of file to store in the logical boot partition 2 region.

Write the content from a file into IFWI region defined by IFWI_FMAP_NAME.

Name of FMAP region to write IFWI.

Name of file to store in the IFWI region.

Include DSP firmware settings for 1 channel 16B DMIC array.

Include DSP firmware settings for 2 channel 16B DMIC array.

Include DSP firmware settings for 4 channel 16B DMIC array.

Include DSP firmware settings for headset codec.

Include DSP firmware settings for headset codec.

Include DSP firmware settings for headset codec.

This option allows you to select how cache-as-ram (CAR) is set up.

Traditionally, CAR is set up by using Non-Evict mode. This method does not allow CAR and cache to co-exist, because cache fills are block in NEM mode.

Cache Quality of Service allows more fine-grained control of cache usage. As result, it is possible to set up portion of L2 cache for CAR and use remainder for actual caching.

Use FSP APIs to initialize & tear down the Cache-As-Ram.

Some Apollo Lake mainboards do not need the Running Average Power Limits (RAPL) algorithm for a constant power management. Set this config option to skip the RAPL configuration.

Use eSPI bus instead of LPC

Bay Trail M/D part support.

Select this option to add a blob containing memory reference code. Note: Without this binary coreboot will not work

The path and filename of the file to use as System Agent binary. Note that this points to the sandybridge binary file which is will not work, but it serves its purpose to do builds.

The size of the cache-as-ram region required during bootblock and/or romstage. Note DCACHE_RAM_SIZE and DCACHE_RAM_MRC_VAR_SIZE must add up to a power of 2.

The amount of cache-as-ram region required by the reference code.

The baytrail romstage code caches the loaded ramstage program in SMM space. On S3 wake the romstage will copy over a fresh ramstage that was cached in the SMM space. This option determines the action to take when the ramstage cache is invalid. If selected the system will reset otherwise the ramstage will be reloaded from cbfs.

The PMC has a legacy COM1 serial port. Choose this option to configure the pads and enable it. This serial port can be used for the debug console.

The reference code blob will be placed into cbfs.

The path and filename to the file to be added to cbfs.

Braswell M/D part support.

The size of the cache-as-ram region required during bootblock and/or romstage. Note DCACHE_RAM_SIZE and DCACHE_RAM_MRC_VAR_SIZE must add up to a power of 2.

The haswell romstage code caches the loaded ramstage program in SMM space. On S3 wake the romstage will copy over a fresh ramstage that was cached in the SMM space. This option determines the action to take when the ramstage cache is invalid. If selected the system will reset otherwise the ramstage will be reloaded from cbfs.

The PMC has a legacy COM1 serial port. Choose this option to configure the pads and enable it. This serial port can be used for the debug console.

Intel Broadwell and Haswell ULT support.

The size of the cache-as-ram region required during bootblock and/or romstage. Note DCACHE_RAM_SIZE and DCACHE_RAM_MRC_VAR_SIZE must add up to a power of 2.

The amount of cache-as-ram region required by the reference code.

Select this option to add a Memory Reference Code binary to the resulting coreboot image.

Note: Without this binary coreboot will not work

The filename of the file to use as Memory Reference Code binary.

On some systems, coreboot boots so fast that connected monitors (mostly TVs) won't be able to wake up fast enough to talk to the VBIOS. On those systems we need to wait for a bit before executing the VBIOS.

The romstage code caches the loaded ramstage program in SMM space. On S3 wake the romstage will copy over a fresh ramstage that was cached in the SMM space. This option determines the action to take when the ramstage cache is invalid. If selected the system will reset otherwise the ramstage will be reloaded from cbfs.

If you set this option to y, the serial IRQ machine will be operated in continuous mode.

The reference code blob will be placed into cbfs.

The path and filename to the file to be added to cbfs.

Intel Cannonlake support

Index for LPSS UART port to use for console: 0 = LPSS UART0, 1 = LPSS UART1, 2 = LPSS UART2

The size of the cache-as-ram region required during bootblock and/or romstage.

The amount of anticipated stack usage in CAR by bootblock and other stages.

Include DSP firmware settings for 1 channel 16B DMIC array.

Include DSP firmware settings for 2 channel 16B DMIC array.

Include DSP firmware settings for 4 channel 16B DMIC array.

Include DSP firmware settings for headset codec.

Include DSP firmware settings for headset codec.

Include DSP firmware settings for headset codec.

This option allows you to select MMIO Base Address of sideband bus.

This option allows you to select how cache-as-ram (CAR) is set up.

A current limitation of NEM (Non-Evict mode) is that code and data sizes are derived from the requirement to not write out any modified cache line. With NEM, if there is no physical memory behind the cached area, the modified data will be lost and NEM results will be inconsistent. ENHANCED NEM guarantees that modified data is always kept in cache while clean data is replaced.

Use FSP APIs to initialize and tear down the Cache-As-Ram.

Intel Denverton-NS SoC support

The memory location of the Intel FSP-T binary for this platform.

The memory location of the Intel FSP-M binary for this platform.

The memory location of the Intel FSP-S binary for this platform.

This option allows you to select MMIO Base Address of sideband bus.

Do not change this value

Disable legacy UART mode

Enable legacy UART mode

A current limitation of NEM (Non-Evict mode) is that code and data sizes are derived from the requirement to not write out any modified cache line. With NEM, if there is no physical memory behind the cached area, the modified data will be lost and NEM results will be inconsistent. ENHANCED NEM guarantees that modified data is always kept in cache while clean data is replaced.

Bay Trail I part support using the Intel FSP.

This is set by the FSP

This is the default PCI ID for the Bay Trail graphics devices. This string names the vbios ROM in cbfs.

The Baytrail SOC has one legacy serial port. Choose this option to configure the pads and enable it. This serial port can be used for the debug console.

The path and filename of the Intel FSP binary for this platform.

The location in CBFS that the FSP is located. This must match the value that is set in the FSP binary. If the FSP needs to be moved, rebase the FSP with Intel's BCT (tool).

The Bay Trail FSP is built with a preferred base address of 0xFFFC0000.

Broadwell-DE support using the Intel FSP.

Use Broadwell-DE Integrated UART ports @3F8h and 2F8h.

If you set this option to y, the serial IRQ machine will be operated in continuous mode.

The path and filename of the Intel FSP binary for this platform.

The location in CBFS that the FSP is located. This must match the value that is set in the FSP binary. If the FSP needs to be moved, rebase the FSP with Intel's BCT (tool).

The Broadwell-DE FSP is built with a preferred base address of 0xffeb0000.

This address needs to match the setup performed inside FSP. On Broadwell-DE the FSP allocates temporary RAM starting at 0xfe100000.

The DCACHE is shared between FSP itself and the rest of the coreboot stages. A size of 0x8000 works fine while providing enough space for features like VBOOT in verstage. Further increase to a power of two aligned value leads to errors in FSP.

Load SPD data from ROM instead of trying to read from SMBus.

If the platform has DIMM sockets, say N. If memory is down, say Y and supply the appropriate SPD data for each Channel/DIMM.

Select Y if Channel 0, DIMM 0 is present.

Path to the file which contains the SPD data for Channel 0, DIMM 0.

Select Y if Channel 0, DIMM 1 is present.

Path to the file which contains the SPD data for Channel 0, DIMM 1.

Select Y if Channel 1, DIMM 0 is present.

Path to the file which contains the SPD data for Channel 1, DIMM 0.

Select Y if Channel 1, DIMM 1 is present.

Path to the file which contains the SPD data for Channel 1, DIMM 1.

Enable Intel(r) Hyper-Threading Technology for the Broadwell-DE SoC.

Enable EHCI controller 1

Enable EHCI controller 2

Intel Quark support

The Quark SoC has two HSUART. Choose this option to configure the pads and enable HSUART0, which can be used for the debug console.

The Quark SoC has two HSUART. Choose this option to configure the pads and enable HSUART1, which can be used for the debug console.

Memory mapped MMIO of HSUART.

Enable the use of the SD LED for early debugging before serial output is available. Setting this LED indicates that control has reached the desired check point.

Indicate that ESRAM has been successfully initialized. If the SD LED does not light then the ESRAM initialization needs to be debugged.

Indicate that fsp.bin was found. If the SD LED does not light then the code between ESRAM initialization through find_fsp needs to debugged. Start by verifying that the correct fsp.bin is in the image.

Indicate that bootblock_c_entry was entered. If the SD LED does not light then debug the code between ESRAM and bootblock_c_entry. For FSP 1.1, use ENABLE_DEBUG_LED_FINDFSP to split this code.

Indicate that bootblock_soc_early_init was entered. If the SD LED does not light then debug the code in bootblock_main_with_timestamp.

Indicate that bootblock_soc_early_init exited. If the SD LED does not light then debug the scripts in bootblock_soc_early_init.

Indicate that bootblock_soc_init was entered. If the SD LED does not light then debug the code in bootblock_mainboard_early_init and console_init. If the SD LED does light but there is no serial then debug the serial port configuration and initialization.

Select this option to display coreboot's use of ESRAM.

Specify the size of the coreboot file system in the read-only (recovery) portion of the flash part. On Quark systems the firmware image stores more than just coreboot, including: - The chipset microcode (RMU) binary file located at 0xFFF00000 - Intel Trusted Execution Engine firmware

Select this option to add an Intel FSP binary to the resulting coreboot image.

Note: Without this binary, coreboot builds relying on the FSP will not boot

The path and filename of the Intel FSP binary for this platform.

The location in CBFS that the FSP is located. This must match the value that is set in the FSP binary. If the FSP needs to be moved, rebase the FSP with Intel's BCT (tool).

The location in ESRAM where a copy of the FSP binary is placed.

Relocate the FSP binary into DRAM before the call to SiliconInit.

The RMU file is required to get the chip out of reset.

The path and filename of the Intel Quark RMU binary.

The location in CBFS that the RMU is located. It must match the strap-determined base address.

Read block 0 from each parition of the storage device. User must also enable one or both of COMMONLIB_STORAGE_SD or COMMONLIB_STORAGE_MMC.

Display the I2C segments and controller errors

Intel Skylake support

Intel Kabylake support

The size of the cache-as-ram region required during bootblock and/or romstage.

The amount of anticipated stack usage in CAR by bootblock and other stages.

If you set this option to n, will not use native SD controller.

This option allows you to select MMIO Base Address of sideband bus.

If you set this option to y, the serial IRQ machine will be operated in continuous mode.

Index for LPSS UART port to use for console: 0 = LPSS UART0, 1 = LPSS UART1, 2 = LPSS UART2

Choose this option if you have a PCH-H chipset.

Include DSP firmware settings for 2 channel DMIC array.

Include DSP firmware settings for 4 channel DMIC array.

Include DSP firmware settings for nau88l25 headset codec.

Include DSP firmware settings for max98357 amplifier.

Include DSP firmware settings for max98373 amplifier.

Include DSP firmware settings for ssm4567 smart amplifier.

Include DSP firmware settings for rt5514 DSP.

Include DSP firmware settings for rt5663 headset codec.

Include DSP firmware settings for max98927 amplifier.

Include DSP firmware settings for DA7219 headset codec.

This option allows you to select how cache-as-ram (CAR) is set up.

A current limitation of NEM (Non-Evict mode) is that code and data sizes are derived from the requirement to not write out any modified cache line. With NEM, if there is no physical memory behind the cached area, the modified data will be lost and NEM results will be inconsistent. ENHANCED NEM guarantees that modified data is always kept in cache while clean data is replaced.

Use FSP APIs to initialize and tear down the Cache-As-Ram.

Skip Cache as RAM setup in FSP.

Choose this option if you want to disable 8042 Keyboard

common code for Intel SOCs

SoC driver for intel common IP code

Intel Processor common TIMER support

Intel Processor common XDCI support

Intel Processor common storage and communication subsystem support

Intel Processor common SATA support

SATA PCI configuration space offset 0x92 Port implement register bit 0-2 represents respective SATA port enable status as in 0 = Disable; 1 = Enable. If this option is selected then port enable status will be inverted as in 0 = Enable; 1 = Disable.

Use common LPC code for platform. Only soc specific code needs to be implemented as per requirement.

By default COMA range to LPC is enable. COMB range to LPC is optional and should select based on platform dedicated selection.

Intel Processor common SPI support

Intel Processor common P2SB driver

Intel Processor common SMM support

Intel Processor trap flag if it is supported

Time in milliseconds that SLP_SMI for S5 waits for before enabling sleep. This is required to avoid any race between SLP_SMI and PWRBTN SMI.

Intel Processor common System Agent support

This option allows you to select length of PCIEX region.

This option allows you to add the isolated memory ranges (IMRs).

This option allows you to add the DMA Protected Range (DPR).

Intel Processor common High Definition Audio driver support

Intel Processor common LPSS support

Intel Processor common FAST_SPI support

Disable the write status SPI opcode in Intel Fast SPI block.

Intel Processor common UART support

Clock m-divisor value for m/n divider

Clock m-divisor value for m/n divider

Intel Processor Common GSPI support

The input clock speed into the SPI controller IP block, in MHz. No default is set here as this is an SOC-specific value and must be provided by the SOC.

Maximum number of GSPI controllers supported by the PCH. SoC must define this config if SOC_INTEL_COMMON_BLOCK_GSPI is selected.

Intel Processor Common GSPI support with quirks to handle SPI_CS_CONTROL changes introduced in CNL.

Intel Processor common XHCI support

Intel Processor common PCIE support

Enable debug logs in PCIe module. Allows debug information on memory base and limit, prefetchable memory base and limit, prefetchable memory base upper 32 bits and prefetchable memory limit upper 32 bits.

Intel Processor common Private configuration registers (PCR)

The mapping of addresses via the SBREG_BAR assumes the IOSF-SB agents are using 32-bit aligned accesses for their configuration registers. For IOSF versions greater than 1_0, IOSF-SB agents can use any access (8/16/32 bit aligned) for their configuration registers

Intel Processor common code for ACPI

Intel Processor common RTC support

This option selects Intel Common CPU Model support code which provides various CPU related APIs which are common between all Intel Processor families. Common CPU code is supported for SOCs starting from SKL,KBL,APL, and future.

This option selects Intel Common CPU MP Init code. In this common MP Init mechanism, the MP Init is occurring before calling FSP Silicon Init. Hence, MP Init will be pulled to BS_DEV_INIT_CHIPS Entry. And on Exit of BS_DEV_INIT, it is ensured that all MTRRs are re-programmed based on the DRAM resource settings.

This option allows you to select how cache-as-ram (CAR) is set up.

Traditionally, CAR is set up by using Non-Evict mode. This method does not allow CAR and cache to co-exist, because cache fills are blocked in NEM.

Cache Quality of Service allows more fine-grained control of cache usage. As result, it is possible to set up a portion of L2 cache for CAR and use the remainder for actual caching.

A current limitation of NEM (Non-Evict mode) is that code and data sizes are derived from the requirement to not write out any modified cache line. With NEM, if there is no physical memory behind the cached area, the modified data will be lost and NEM results will be inconsistent. ENHANCED NEM guarantees that modified data is always kept in cache while clean data is replaced.

Driver for communication with Converged Security Engine (CSE) over Host Embedded Controller Interface (HECI)

Intel Processor common EBDA library support

Intel Processor common code for Power Management controller(PMC) subsystem

Choose this option if you want to keep system into S5 after reapplying power after failure

Choose this option if you want to keep system into S0 after reapplying power after failure

Choose this option if you want to keep system into same power state as before failure even after reapplying power

Enable this for PMC devices where a read back of ACPI BAR and IO access bit does not return the previously written value.

Intel Processor common SMBus support

Intel Processor common GPIO support

This option enables GPIO debug messages

Software Guard eXtension(SGX) Feature. Intel SGX is a set of new CPU instructions that can be used by applications to set aside private regions of code and data.

Intel Processor common DSP support

Intel Processor Common I2C support

Enable debug output for I2C transactions. This can be useful when debugging I2C drivers.

Intel Processor common SRAM support

Intel Processor common interrupt timer subsystem support

Intel Processor common Graphics support

Provide a mechanism for serial console based ACPI debug.

Set this option to y to enable MMA (Memory Margin Analysis) support

acpi_get_gpe() is used to provide interrupt status to TPM layer. This option specifies the GPE number.

AMD Stoney Ridge FP4 support

AMD Stoney Ridge FT4 support

The amount of anticipated stack usage in CAR by bootblock and other stages.

Increase this value if preram cbmem console is getting truncated

If PCI peripherals with big BARs are connected to the system the bottom of the IO must be decreased to allocate such devices.

Declare the beginning of the 128MB-aligned MMIO region. This option is useful when PCI peripherals requesting large address ranges are present.

The default VGA BIOS PCI vendor/device ID should be set to the result of the map_oprom_vendev() function in northbridge.c.

The XHCI controller must be enabled and the XHCI firmware must be added in order to have USB 3.0 support configured by coreboot. The OS will be responsible for enabling the XHCI controller if the the XHCI firmware is available but the XHCI controller is not enabled by coreboot.

Add Stoney Ridge XHCI Firmware to support the onboard USB 3.0

Add Stoney Ridge IMC Firmware to support the onboard fan control

Add Stoney Ridge GEC Firmware to support the onboard gigabit Ethernet MAC. Must be connected to a Broadcom B50610 or B50610M PHY on the motherboard.

Select the mode in which SATA should be driven. The default is NATIVE. 0: NATIVE mode does not require a ROM. 2: AHCI may work with or without AHCI ROM. It depends on the payload support. For example, seabios does not require the AHCI ROM. 3: LEGACY IDE 4: IDE to AHCI 5: AHCI7804: ROM Required, and AMD driver required in the OS. 6: IDE to AHCI7804: ROM Required, and AMD driver required in the OS.

Select y if there is no keyboard controller in the system. This sets variables in AGESA and ACPI.

Set this option to y for serial IRQ in continuous mode. Otherwise it is in quiet mode.

Base address for the ACPI registers. This value must match the hardcoded value of AGESA.

There are two UART controllers in Stoney Ridge. The UART registers are memory-mapped. UART controller 0 registers range from FEDC_6000h to FEDC_6FFFh. UART controller 1 registers range from FEDC_8000h to FEDC_8FFFh.

Include the PspSecureOs, PspTrustlet and TrustletKey binaries in the amdfw section.

If unsure, answer 'y'

The AMDFW (PSP) is typically locatable in cbfs. Select this option to manually attach the generated amdfw.rom outside of cbfs. The location is selected by the FWM position.

Typically this is calculated by the ROM size, but there may be situations where you want to put the firmware directory table in a different location. 0: 512 KB - 0xFFFA0000 1: 1 MB - 0xFFF20000 2: 2 MB - 0xFFE20000 3: 4 MB - 0xFFC20000 4: 8 MB - 0xFF820000 5: 16 MB - 0xFF020000

This option determines what state to go to once power is restored after having been lost in S0. Select this option to automatically return to S0. Otherwise the system will remain in S5 once power is restored.

This option determines if all files under vendorcode/amd/pi/00670F00/ will be compiled or only selected procedures of source files (minimum required).

common code for AMD SOCs

SoC driver for AMD common IP code

Select this option to add S3 related functions to the build.

This option builds functions that interface AMD's AGESA.

This option builds functions used to program PCI interrupt routing, both PIC and APIC modes.

This option allows the SOC to use a standard AMD cache-as-ram (CAR) implementation. CAR setup is built into bootblock and teardown is in postcar. The teardown procedure does not preserve the stack so it may not be appropriate for a romstage implementation without additional consideration. If this option is not used, the SOC must implement these functions separately.

This option builds in the Platform Security Processor initialization functions.

Some PSP implementations allow storing SMU firmware into cbfs and calling the PSP to load the blobs at the proper time.

The soc/<codename> should select this if its PSP supports the feature and each mainboard can choose to select an appropriate fanless or fanned set of blobs. Ask your AMD representative whether your APU is considered fanless.

Warning: M0 expects that auto self-refresh is enabled. Modify with caution.

This option enables additional DRAM related debug messages.

This option enables I2C related debug messages.

This option enables PMIC related debug messages.

This option enables PMIC WRAP related debug messages.

Map the UART to the respective MMIO address

Baud rate for the UART

Is the SoC a QFN part (as opposed to a BGA part)

The path and filename of the binary blob containing ipq40xx early initialization code, as supplied by the vendor.

Path for utils to combine SBL_ELF and bootblock

The path and filename of the binary blob containing ipq806x early initialization code, as supplied by the vendor.

Select Spread Spectrum Modulator (SSMOD) is a fully-digital circuit used to modulate the frequency of the Silicon Creations' Fractional PLL in order to reduce EMI.

The haswell romstage code caches the loaded ramstage program in SMM space. On S3 wake the romstage will copy over a fresh ramstage that was cached in the SMM space. This option determines the action to take when the ramstage cache is invalid. If selected the system will reset otherwise the ramstage will be reloaded from cbfs.

This option selects building a Firmware Interface Table (FIT).

This option selects the number of empty entries in the FIT table.

This option indicates that the turbo mode setting is not package scoped. i.e. enable_turbo() needs to be called on not just the bsp

Although the Intel manual says you must set the lock bit in addition to the VMX bit in order for VMX to work, this isn't strictly true, so we have the option to leave it unlocked and allow the OS (e.g. Linux) to manage things itself. This is beneficial for testing purposes as there is no need to reflash the firmware just to toggle the lock bit. However, leaving the lock bit unset will break Windows' detection of VMX support and built-in virtualization features like Hyper-V.

Select this option if you have an AMD Geode LX vsa that you would like to add to your ROM.

You will be able to specify the location and file name of the image later.

The path and filename of the file to use as VSA.

Overwride the default write through caching size as 1M Bytes. On some AMD platforms, one socket supports 2 or more kinds of processor family, compiling several CPU families agesa code will increase the romstage size. In order to execute romstage in place on the flash ROM, more space is required to be set as write through caching.

Try to restore memory training results from non-volatile memory.

Force AGESA to ignore package type mismatch between CPU and northbridge in memory code. This enables Socket AM1 support with current AGESA version for Kabini platform. Enable this option only if you have Socket AM1 board. Note that the AGESA release shipped with coreboot does not officially support the AM1 socket. Selecting this option might damage your hardware.

Overwride the default write through caching size as 1M Bytes. On some AMD platforms, one socket supports 2 or more kinds of processor family, compiling several CPU families agesa code will increase the romstage size. In order to execute romstage in place on the flash ROM, more space is required to be set as write through caching.

This option uses common MP infrastructure for bringing up APs in parallel. It additionally provides a more flexible mechanism for sequencing the steps of bringing up the APs.

Allow APs to do other work after initialization instead of going to sleep.

Expose monotonic time using the local APIC.

This option asserts that the TSC ticks at a known constant rate. Therefore, no TSC calibration is required.

Expose monotonic time using the TSC.

The CPU driver should select this if the CPU needs to execute an lfence instruction in order to synchronize rdtsc. This is true for all modern AMD CPUs.

The CPU driver should select this if the CPU needs to execute an mfence instruction in order to synchronize rdtsc. This is true for all modern Intel CPUs.

The XIP_ROM_SIZE Kconfig variable is used globally on x86 with the assumption that all chipsets utilize this value. For the chipsets which do not use the variable it can lead to unnecessary alignment constraints in cbfs for romstage. Therefore, allow those chipsets a path to not be burdened.

This option determines the size of the heap within the SMM handler modules.

On some CPUs, there is a race condition in SMM. This can occur when both hyperthreads change SMM state variables in parallel without coordination. Setting this option serializes the SMM initialization to avoid an ugly hang in the boot process at the cost of a slightly longer boot time.

This option informs the MTRR code to use the RdMem and WrMem fields in the fixed MTRR MSRs.

Selected for Intel processors/platform combinations that use the Intel Firmware Support Package (FSP) 1.0 for initialization.

On certain platforms a boot speed gain can be realized if mirroring the payload data stored in non-volatile storage. On x86 systems the payload would typically live in a memory-mapped SPI part. Copying the SPI contents to RAM before performing the load can speed up the boot process.

The SoC requires different access methods for reading and writing the MSRs. Use SoC specific routines to handle the MSR access.

This option is selected if there is no need to migrate CAR globals. All stages which use CAR globals can directly access the variables from their linked addresses.

This option is used to enable certain functions to make coreboot work correctly on symmetric multi processor (SMP) systems.

This must equal address of ap_sipi_vector from bootblock build.

Select MMX in your socket or model Kconfig if your CPU has MMX streaming SIMD instructions. ROMCC can build more efficient code if it can spill to MMX registers.

Select SSE in your socket or model Kconfig if your CPU has SSE streaming SIMD instructions. ROMCC can build more efficient code if it can spill to SSE (aka XMM) registers.

Select SSE2 in your socket or model Kconfig if your CPU has SSE2 streaming SIMD instructions. Some parts of coreboot can be built with more efficient code if SSE2 instructions are available.

This is selected by a board or chipset to set the default for the microcode source choice to a list of external microcode headers

Select this option if you want microcode updates to be assembled when building coreboot and included in the final image as a separate CBFS file. Microcode will not be hard-coded into ramstage.

The microcode file may be removed from the ROM image at a later time with cbfstool, if desired.

If unsure, select this option.

Select this option if you want to include external c header files containing the CPU microcode. This will be included as a separate file in CBFS.

A word of caution: only select this option if you are sure the microcode that you have is newer than the microcode shipping with coreboot.

The microcode file may be removed from the ROM image at a later time with cbfstool, if desired.

If unsure, select "Generate from tree"

Select this option if you do not want CPU microcode included in CBFS. Note that for some CPUs, the microcode is hard-coded into the source tree and is not loaded from CBFS. In this case, microcode will still be updated. There is a push to move all microcode to CBFS, but this change is not implemented for all CPUs.

This option currently applies to: - Intel SandyBridge/IvyBridge - VIA Nano

Microcode may be added to the ROM image at a later time with cbfstool, if desired.

If unsure, select "Generate from tree"

The GOOD: Microcode updates intend to solve issues that have been discovered after CPU production. The expected effect is that systems work as intended with the updated microcode, but we have also seen cases where issues were solved by not applying microcode updates.

The BAD: Note that some operating system include these same microcode patches, so you may need to also disable microcode updates in your operating system for this option to have an effect.

The UGLY: A word of CAUTION: some CPUs depend on microcode updates to function correctly. Not updating the microcode may leave the CPU operating at less than optimal performance, or may cause outright hangups. There are CPUs where coreboot cannot properly initialize the CPU without microcode updates For example, if running with the factory microcode, some Intel SandyBridge CPUs may hang when enabling CAR, or some VIA Nano CPUs will hang when changing the frequency.

Make sure you have a way of flashing the ROM externally before selecting this option.

Select this option to install separate microcode container files into CBFS instead of using the traditional monolithic microcode file format.

A list of one or more microcode header files with path from the coreboot directory. These should be separated by spaces.

Some platforms have microcode in the blobs directory, and these can be hardcoded in the makefiles. For platforms with microcode binaries that aren't in the makefile, set this option to pull in the microcode.

This should contain the full path of the file for one or more microcode binary files to include, separated by spaces.

If unsure, leave this blank.

Selected by mainboards that use native graphics initialization for the LVDS port. A linear framebuffer is only supported for LVDS.

Usually system firmware turns off system memory clock signals to unused SO-DIMM slots to reduce EMI and power consumption. However, some boards do not like unused clock signals to be disabled.

If non-zero, this designates the maximum DDR frequency the board supports, despite what the chipset should be capable of.

On some boards it may be neccessary to hard reset early during resume from S3 if the SLFRCS register indicates that a memory channel is not guaranteed to be in self-refresh. On other boards the check always creates a false positive, effectively making it impossible to resume.

Select if you want to use coreboot implementation of raminit rather than System Agent/MRC.bin. You should answer Y.

Ignore the mainboard's vendor programmed fuses that might limit the maximum DRAM frequency. By selecting this option the fuses will be ignored and the only limits on DRAM frequency are set by RAM's SPD and hard fuses in southbridge's clockgen. Disabled by default as it might causes system instability. Handle with care!

Ignore the max DIMMs per channel restriciton defined in XMP profiles. Disabled by default as it might cause system instability. Handle with care!

The MRC blob requires it to be at 0xf0000000.

The path and filename of the file to use as System Agent binary.

The size of the cache-as-ram region required during bootblock and/or romstage. Note DCACHE_RAM_SIZE and DCACHE_RAM_MRC_VAR_SIZE must add up to a power of 2.

The amount of cache-as-ram region required by the reference code.

The amount of anticipated stack usage from the data cache during pre-ram ROM stage execution.

Select this option to add a System Agent binary to the resulting coreboot image.

Note: Without this binary coreboot will not work

The path and filename of the file to use as System Agent binary.

On some systems, coreboot boots so fast that connected monitors (mostly TVs) won't be able to wake up fast enough to talk to the VBIOS. On those systems we need to wait for a bit before executing the VBIOS.

This is the default PCI ID for the sandybridge/ivybridge graphics devices. This string names the vbios ROM in cbfs. The following PCI IDs will be remapped to load this ROM: 0x80860102, 0x8086010a, 0x80860112, 0x80860116 0x80860122, 0x80860126, 0x80860166

The path and filename of the Intel FSP binary for this platform.

The location in CBFS that the FSP is located. This must match the value that is set in the FSP binary. If the FSP needs to be moved, rebase the FSP with the Intel's BCT (tool).

The Ivy Bridge Processor/Panther Point FSP is built with a preferred base address of 0xFFF80000

This option affects how the SDRAMC register is programmed. Memory clock signals will not be routed properly if this option is set wrong.

If your board has 4 DIMM slots, you must use select this option, in your Kconfig file of the board. On boards with 3 DIMM slots, do _not_ select this option.

Set the TSEG area to 1 MB.

Set the TSEG area to 2 MB.

Set the TSEG area to 4 MB.

Set the TSEG area to 8 MB.

The path and filename of the Intel FSP binary for this platform.

The location in CBFS that the FSP is located. This must match the value that is set in the FSP binary. If the FSP needs to be moved, rebase the FSP with Intel's BCT (tool).

The Rangeley FSP is built with a preferred base address of 0xFFF80000

If PCI peripherals with big BARs are connected to the system the bottom of the IO must be decreased to allocate such devices.

Declare the beginning of the 128MB-aligned MMIO region. This option is useful when PCI peripherals requesting large address ranges are present.

The default VGA BIOS PCI vendor/device ID should be set to the result of the map_oprom_vendev() function in northbridge.c.

The default VGA BIOS PCI vendor/device ID should be set to the result of the map_oprom_vendev() function in northbridge.c.

The default VGA BIOS PCI vendor/device ID should be set to the result of the map_oprom_vendev() function in northbridge.c.

The default VGA BIOS PCI vendor/device ID should be set to the result of the map_oprom_vendev() function in northbridge.c.

Select this for boards with a Voltage Regulator able to operate at 3.4 MHz in SVI mode. Ignored unless the AMD CPU is rev C3.

This option sets the maximum permissible HyperTransport downlink width.

Use of this option will only limit the autodetected HT width. It will not (and cannot) increase the width beyond the autodetected limits.

This is primarily used to work around poorly designed or laid out HT traces on certain motherboards.

This option sets the maximum permissible HyperTransport uplink width.

Use of this option will only limit the autodetected HT width. It will not (and cannot) increase the width beyond the autodetected limits.

This is primarily used to work around poorly designed or laid out HT traces on certain motherboards.

If you set this option to y, the serial IRQ machine will be operated in continuous mode.

Set this option to y for Lynxpont LP (Haswell ULT).

If you set this option to y, the serial IRQ machine will be operated in continuous mode.

If you set this option to y, the Management Engine driver will defer waiting for the MBP Cleared indicator until the finalize step. This can speed up boot time if the ME takes a long time to indicate this status.

If you set this option to y, the USB ports will be routed to the XHCI controller during the finalize SMM callback.

If you set this option to y, the serial IRQ machine will be operated in continuous mode.

Select this if you want to write-protect the whole firmware flash chip. The locking will take place during the chipset lockdown, which is either triggered by coreboot (when INTEL_CHIPSET_LOCKDOWN is set) or has to be triggered later (e.g. by the payload or the OS).

NOTE: If you trigger the chipset lockdown unconditionally, you won't be able to write to the flash chip using the internal programmer any more.

Select this if you want to protect the firmware flash against all further accesses (with the exception of the memory mapped BIOS re- gion which is always readable). The locking will take place during the chipset lockdown, which is either triggered by coreboot (when INTEL_CHIPSET_LOCKDOWN is set) or has to be triggered later (e.g. by the payload or the OS).

NOTE: If you trigger the chipset lockdown unconditionally, you won't be able to write to the flash chip using the internal programmer any more.

If you set this option to y, the serial IRQ machine will be operated in continuous mode.

Some registers within host bridge on particular chipsets should be locked down on each normal boot path (done by either coreboot or payload) and S3 resume (always done by coreboot). Select this to let coreboot to do this on normal boot path.

If you set this option to y, the serial IRQ machine will be operated in continuous mode.

The path and filename to the descriptor.bin file.

If you set this option to y, the serial IRQ machine will be operated in continuous mode.

The XHCI controller must be enabled and the XHCI firmware must be added in order to have USB 3.0 support configured by coreboot. The OS will be responsible for enabling the XHCI controller if the the XHCI firmware is available but the XHCI controller is not enabled by coreboot.

Add Hudson 2/3/4 XHCI Firmware to support the onboard USB 3.0

Add Hudson 2/3/4 IMC Firmware to support the onboard fan control

Add Hudson 2/3/4 GEC Firmware to support the onboard gigabit Ethernet MAC. Must be connected to a Broadcom B50610 or B50610M PHY on the motherboard.

Select the mode in which SATA should be driven. NATIVE AHCI, or RAID. The default is NATIVE. 0: NATIVE mode does not require a ROM. 1: RAID mode must have the two ROM files. 2: AHCI may work with or without AHCI ROM. It depends on the payload support. For example, seabios does not require the AHCI ROM. 3: LEGACY IDE 4: IDE to AHCI 5: AHCI7804: ROM Required, and AMD driver required in the OS. 6: IDE to AHCI7804: ROM Required, and AMD driver required in the OS.

1022,7802 for SATA NON-RAID5 module, 1022,7803 for SATA RAID5 mode

The RAID ROM requires that the MISC ROM is located between the range 0xFFF0_0000 to 0xFFF0_FFFF. Also, it must 1K bytes aligned. The CONFIG_ROM_SIZE must be larger than 0x100000.

Select y if there is no keyboard controller in the system. This sets variables in AGESA and ACPI.

bit 1,0 - pin 0 bit 3,2 - pin 1 bit 5,4 - pin 2 bit 7,6 - pin 3

The AMDFW (PSP) is typically locatable in cbfs. Select this option to manually attach the generated amdfw.rom at an offset of 0x20000 from the bottom of the coreboot ROM image.

Set this option to y for serial IRQ in continuous mode. Otherwise it is in quiet mode.

Base address for the ACPI registers. This value must match the hardcoded value of AGESA.

There are two UART controllers in Kern. The UART registers are memory-mapped. UART controller 0 registers range from FEDC_6000h to FEDC_6FFFh. UART controller 1 registers range from FEDC_8000h to FEDC_8FFFh.

If Combined Mode is enabled. IDE controller is exposed and SATA controller has control over Port0 through Port3, IDE controller has control over Port4 and Port5.

If Combined Mode is disabled, IDE controller is hidden and SATA controller has full control of all 6 Ports when operating in non-IDE mode.

Select the mode in which SATA should be driven. NATIVE AHCI, or RAID. The default is AHCI.

NATIVE does not require a ROM.

AHCI is the default and may work with or without AHCI ROM. It depends on the payload support. For example, seabios does not require the AHCI ROM.

sb800 RAID mode must have the two required ROM files.

1002,4392 for SATA NON-RAID5 module, 1002,4393 for SATA RAID5 mode

The RAID ROM requires that the MISC ROM is located between the range 0xFFF0_0000 to 0xFFF0_FFFF. Also, it must 1K bytes aligned. The CONFIG_ROM_SIZE must larger than 0x100000.

Add SB800 / Hudson 1 IMC Firmware to support the onboard fan control.

The IMC and GEC ROMs requires a 'signature' located at one of several fixed locations in memory. The location used shouldn't matter, just select an area that doesn't conflict with anything else.

The IMC and GEC ROMs requires a 'signature' located at one of several fixed locations in memory. The location used shouldn't matter, just select an area that doesn't conflict with anything else.

The IMC and GEC ROMs requires a 'signature' located at one of several fixed locations in memory. The location used shouldn't matter, just select an area that doesn't conflict with anything else.

The IMC and GEC ROMs requires a 'signature' located at one of several fixed locations in memory. The location used shouldn't matter, just select an area that doesn't conflict with anything else.

The IMC and GEC ROMs requires a 'signature' located at one of several fixed locations in memory. The location used shouldn't matter, just select an area that doesn't conflict with anything else.

Select the method of SB800 fan control to be used. None would be for either fixed maximum speed fans connected to the SB800 or for an external chip controlling the fan speeds. Manual control sets up the SB800 fan control registers. IMC fan control uses the SB800 IMC to actively control the fan speeds.

No SB800 Fan control - Do not set up the SB800 fan control registers.

Configure the SB800 fan control registers in devicetree.cb.

Set up the SB800 to use the IMC based Fan controller. This requires the IMC ROM from AMD. Configure the registers in devicetree.cb.

0x0 = Native IDE mode. 0x1 = RAID mode. 0x2 = AHCI mode. 0x3 = Legacy IDE mode. 0x4 = IDE->AHCI mode. 0x5 = AHCI mode as 7804 ID (AMD driver). 0x6 = IDE->AHCI mode as 7804 ID (AMD driver).

n = Disable PCI Bridge Device 14 Function 4. y = Enable PCI Bridge Device 14 Function 4.

Set SCI IRQ to 9.

Select to enable PCI-E MMCONFIG support on the SR5650.

The XHCI controller must be enabled and the XHCI firmware must be added in order to have USB 3.0 support configured by coreboot. The OS will be responsible for enabling the XHCI controller if the the XHCI firmware is available but the XHCI controller is not enabled by coreboot.

Add Hudson 2/3/4 XHCI Firmware to support the onboard USB 3.0

Add Hudson 2/3/4 IMC Firmware to support the onboard fan control

Add Hudson 2/3/4 GEC Firmware to support the onboard gigabit Ethernet MAC. Must be connected to a Broadcom B50610 or B50610M PHY on the motherboard.

Select the mode in which SATA should be driven. NATIVE AHCI, or RAID. The default is NATIVE. 0: NATIVE mode does not require a ROM. 1: RAID mode must have the two ROM files. 2: AHCI may work with or without AHCI ROM. It depends on the payload support. For example, seabios does not require the AHCI ROM. 3: LEGACY IDE 4: IDE to AHCI 5: AHCI7804: ROM Required, and AMD driver required in the OS. 6: IDE to AHCI7804: ROM Required, and AMD driver required in the OS.

1022,7802 for SATA NON-RAID5 module, 1022,7803 for SATA RAID5 mode

The RAID ROM requires that the MISC ROM is located between the range 0xFFF0_0000 to 0xFFF0_FFFF. Also, it must 1K bytes aligned. The CONFIG_ROM_SIZE must be larger than 0x100000.

Select y if there is no keyboard controller in the system. This sets variables in AGESA and ACPI.

bit 1,0 - pin 0 bit 3,2 - pin 1 bit 5,4 - pin 2 bit 7,6 - pin 3

When set, the SPI clock will run at 33MHz instead of the compatibility mode 16.5MHz. Note that not all ROMs are capable of 33MHz operation, so you will need to verify this option is appropriate for the ROM you are using.

Skip the CS5536 early SMBUS initialization.

Enable extended, 16-bit wide tacho counters.

PWM duty cycles are set in 8-bit registers (instead of 7 bit).

The second FAN controller has a separate frequency setting.

ACPI Embedded Controller interface. Mostly found in laptops.

Google's Chrome EC

When defined, ACPI accesses EC memmap data on ports 66h/62h. When not defined, the memmap data is instead accessed on 900h-9ffh via the LPC bus.

Expose methods for enabling and disabling port power on individual USB ports through the EC.

Provides common routine for reading boardid from Chrome EC.

Google's Chrome EC via I2C bus.

Use only proto3 for i2c EC communication.

Google Chrome EC via LPC bus.

Microchip EC variant for LPC register access.

Indicates that Google's Chrome USB PD chip is present.

Google's Chrome EC via SPI bus.

Force delay after asserting /CS to allow EC to wakeup.

The board name used in the Chrome EC code base to build the EC firmware. If set, the coreboot build with also build the EC firmware and add it to the image.

The board name used in the Chrome EC code base to build the PD firmware. If set, the coreboot build with also build the EC firmware and add it to the image.

Enable support for the real-time clock on the Chrome OS EC. This uses the EC_CMD_RTC_GET_VALUE command to read the current time.

Disable building and including any EC firmware in the image.

config EC_GOOGLE_CHROMEEC_FIRMWARE_EXTERNAL bool "External EC firmware is included" help Include EC firmware binary in the image from an external source. It is expected to be built externally.

config EC_GOOGLE_CHROMEEC_FIRMWARE_BUILTIN bool "Builtin EC firmware is included" help Build and include EC firmware binary in the image.

The path and filename of the EC firmware file to use.

Disable building and including any PD firmware in the image.

config EC_GOOGLE_CHROMEEC_PD_FIRMWARE_EXTERNAL bool "External PD firmware is included" help Include PD firmware binary in the image from an external source. It is expected to be built externally.

config EC_GOOGLE_CHROMEEC_PD_FIRMWARE_BUILTIN bool "Builtin PD firmware is included" help Build and include PD firmware binary in the image.

The path and filename of the PD firmware file to use.

Enable support for Chrome OS mode switches provided by the Chrome OS EC.

Interface to QUANTA IT8518 Embedded Controller.

Interface to QUANTA ENE KB3940Q Embedded Controller.

Interface to SMSC KBC1126 embedded controller in HP laptops.

Select this option to add the two firmware blobs for KBC1126. You need these two blobs to power on your machine.

The path and filename of the file to use as KBC1126 firmware #1. You can use util/kbc1126/kbc1126_ec_dump to dump it from the vendor firmware.

The path and filename of the file to use as KBC1126 firmware #2. You can use util/kbc1126/kbc1126_ec_dump to dump it from the vendor firmware.

Beep when encountered a fatal error.

Flash all LEDs when encountered a fatal error.

Disable BDC detection and assume bluetooth is installed. Required for bluetooth on wifi cards, as it's not possible to detect it in coreboot.

Interface to IT8518 embedded controller in Roda notebooks.

Shared memory mailbox interface to SMSC MEC1308 Embedded Controller.

Purism Librem EC

Interface to COMPAL ENE932 Embedded Controller.

Kontron uses an ITE IT8516E on the KTQM77. Its firmware might come from Fintek (mentioned as Finte*c* somewhere in their Linux driver). The KTQM77 is an embedded board and the IT8516E seems to be only used for fan control and GPIO.

Select this option to add an Intel FSP binary to the resulting coreboot image.

Note: Without this binary, coreboot builds relying on the FSP will not boot

The path and filename of the Intel FSP binary for this platform.

The location in CBFS that the FSP is located. This must match the value that is set in the FSP binary. If the FSP needs to be moved, rebase the FSP with Intel's BCT (tool).

Enabling this feature will force the MRC data to be cached in NV storage to be used for speeding up boot time on future reboots and/or power cycles.

Enabling this feature will cause MRC data to be cached in NV storage. This can either be used for fast boot, or just because the FSP wants it to be saved.

Use the region "RW_MRC_CACHE" in FMAP instead of "mrc.cache" in CBFS. You must define a region in your FMAP named "RW_MRC_CACHE".

This is the amount of space in NV storage that is reserved for the fast boot data cache storage.

WARNING: Because this area will be erased and re-written, the size should be a full sector of the flash ROM chip and nothing else should be included in CBFS in any sector that the fast boot cache data is in.

This is used to calculate the offset of the MRC data cache in NV Storage for fast boot. If in doubt, leave this set to the default which sets the virtual size equal to the ROM size.

Example: Cougar Canyon 2 has two 8 MB SPI ROMs. When the SPI ROMs are loaded with a 4 MB coreboot image, the virtual ROM size is 8 MB. When the SPI ROMs are loaded with an 8 MB coreboot image, the virtual ROM size is 16 MB.

The chipset can select this to use a generic cache_as_ram.inc file that should be good for all FSP based platforms.

If this FSP uses UPD/VPD data regions, select this in the chipset Kconfig.

Chipset uses the Intel Firmware Descriptor to describe the layout of the SPI ROM chip.

The descriptor binary

Set SPI frequency to 20MHz and disable Dual Output Fast Read Support

The Intel processor in the selected system requires a special firmware for an integrated controller. This might be called the Management Engine (ME), the Trusted Execution Engine (TXE) or something else depending on the chip. This firmware might or might not be available in coreboot's 3rdparty/blobs repository. If it is not and if you don't have access to the firmware from elsewhere, you can still build coreboot without it. In this case however, you'll have to make sure that you don't overwrite your ME/TXE firmware on your flash ROM.

Verify the integrity of the supplied Intel ME/TXE firmware before proceeding with the build, in order to prevent an accidental loading of a corrupted ME/TXE image.

Use me_cleaner to remove all the non-fundamental code from the Intel ME/TXE firmware. The resulting Intel ME/TXE firmware will have only the code responsible for the very basic hardware initialization, leaving the ME/TXE subsystem essentially in a disabled state.

Don't flash a modified ME/TXE firmware and a new coreboot image at the same time, test them in two different steps.

WARNING: this tool isn't based on any official Intel documentation but only on reverse engineering and trial & error.

See the project's page https://github.com/corna/me_cleaner or the wiki https://github.com/corna/me_cleaner/wiki/How-to-apply-me_cleaner https://github.com/corna/me_cleaner/wiki/How-does-it-work%3F https://github.com/corna/me_cleaner/wiki/me_cleaner-status for more info about this tool

If unsure, say N.

The integrated gigabit ethernet controller needs a firmware file. Select this if you are going to use the PCH integrated controller and have the firmware.

The embedded controller needs a firmware file.

Select this if you are going to use the PCH integrated controller and have the EC firmware. EC firmware will be added to final image through ifdtool.

If you don't have an Intel Firmware Descriptor (descriptor.bin) for your board, you can select this option and coreboot will build without it. The resulting coreboot.rom will not contain all parts required to get coreboot running on your board. You can however write only the BIOS section to your board's flash ROM and keep the other sections untouched. Unfortunately the current version of flashrom doesn't support this yet. But there is a patch pending [1].

WARNING: Never write a complete coreboot.rom to your flash ROM if it was built with a fake IFD. It just won't work.

[1] http://www.flashrom.org/pipermail/flashrom/2013-June/011083.html

The BIOS region is typically the size of the CBFS area, and is located at the end of the ROM space.

For an 8MB ROM with a 3MB CBFS area, this would look like: 0x00500000:0x007fffff

The ME/TXE region typically starts at around 0x1000 and often fills the ROM space not used by CBFS.

For an 8MB ROM with a 3MB CBFS area, this might look like: 0x00001000:0x004fffff

The Gigabit Ethernet ROM region is used when an Intel NIC is built into the Southbridge/SOC and the platform uses this device instead of an external PCIe NIC. It will be located between the ME/TXE and the BIOS region.

Leave this empty if you're unsure.

The Platform region is used for platform specific data. It will be located between the ME/TXE and the BIOS region.

Leave this empty if you're unsure.

The Intel Firmware Descriptor supports preventing write accesses from the host to the ME or TXE section in the firmware descriptor. If the section is locked, it can only be overwritten with an external SPI flash programmer. You will want this if you want to increase security of your ROM image once you are sure that the ME/TXE firmware is no longer going to change.

If unsure, say N.

Reduce CBFS size to give room to the IFD blobs.

UEFI Development Kit version for Platform

Select the method for including the AMD Platform Initialization code into coreboot. Platform Initialization code is required for all AMD processors.

Use a binary PI package. Generally, these will be stored in the "3rdparty/blobs" directory. For some processors, these must be obtained directly from AMD Embedded Processors Group (http://www.amdcom/embedded).

Build the PI package ("AGESA") from source code in the "vendorcode" directory.

Specify where to find the AGESA header files for AMD platform initialization.

Specify the binary file to use for AMD platform initialization.

AGESA will be added as a stage utilizing --xip cbfstool options as needed relocating the image to the proper location in memory-mapped cpu address space. It's required that the file be in ELF format containing the relocations necessary for relocating at runtime.

Specifies that AGESA is split into two binaries for pre- and post-memory.

Specify the binary file to use for pre-memory AMD platform initialization.

Specify the binary file to use for post-memory AMD platform initialization.

Specify the ROM address at which to store the binary Platform Initialization code.

Enable ChromeOS specific features like the GPIO sub table in the coreboot table. NOTE: Enabling this option on an unsupported board will most likely break your build.

On some boards the TPM stays powered up in S3. On those boards, booting Windows will break if the TPM resume command is sent during an S3 resume.

This option is needed to add ACPI regulatory domain methods

Disable the platform heirarchy on resume path if the firmware is involved in resume. The hierarchy is disabled prior to jumping to the OS. Note that this option is sepcific to TPM2 boards. This option is auto selected if CHROMEOS because it matches with vboot_reference model which disables the platform hierarchy in the boot loader. However, those operations need to be symmetric on normal boot as well as resume and coreboot is only involved in the resume piece w.r.t. the platform hierarchy.

Provide a common implementation for mainboard version, which returns a formatted 'rev%d' board_id() string.

Enable this option if your RISC-V processor supports compressed instructions (RVC). Currently, this enables RVC for all stages.

Specify ARMv8 extension, for example '1' for ARMv8.1, to control the '-march' option passed into the compiler. Defaults to 0 for vanilla ARMv8 but may be overridden in the SoC's Kconfig.

All ARMv8 implementations are downwards-compatible, so this does not need to be changed unless specific features (e.g. new instructions) are used by the SoC's coreboot code.

Secure OS binary file.

Some early Cortex-A53 revisions had a hardware bug that results in incorrect address calculations in rare cases. This option enables a linker workaround to avoid those cases if your toolchain supports it. Should be selected automatically by SoCs that are affected.

Allow a platform or processor to select to be compiled using the '-march=i586' option instead of the typical '-march=i686'

Platform implements non-volatile storage to cache cbmem_top() over stage transitions and optionally also over S3 suspend.

Enable this in chipset's Kconfig if northbridge does not implement early cbmem_top() call for romstage. CBMEM tables will be allocated late in ramstage, after PCI devices resources are known.

WARNING: Late CBMEM initialization is deprecated. Platforms that don't support early CBMEM initialization will be removed after the release of coreboot 4.7.

Increase this value if preram cbmem console is getting truncated

Initialize BIOS EBDA area early in romstage to allow bootloader to use this region for storing data which can be available across various stages. If user is selecting this option then its users responsibility to perform EBDA initialization call during romstage.

Add a spin (JMP .) in bootblock_crt0.S during early bootblock to wait for a JTAG debugger to break into the execution sequence.

Select this value to provide a routine to save the BIST and timestamp values. The default code places the BIST value in MM0 and the timestamp value in MM2:MM1. Another file is necessary when the CPU does not support the MMx register set.

Add a spin (JMP .) in assembly_entry.S during early verstage to wait for a JTAG debugger to break into the execution sequence.

Add a spin (JMP .) in assembly_entry.S during early romstage to wait for a JTAG debugger to break into the execution sequence.

Do not clear the reboot count immediately after successful boot. Set to allow the payload to control normal/fallback image recovery. Note that it is the responsibility of the payload to reset the normal boot bit to 1 after each successsful boot.

Sets the ACPI name string in the processor scope as written by the acpigen function. Default is \_PR.CPxx. Note that you need the \ escape character in the string.

Use a non-TSC platform-dependent source for timestamps.

Use the TSC as the timestamp source.

Chipsets scan select this option to preallocate area in cache-as-ram for storing paging data structures. PAE paging is currently the only thing being supported.

The number of 4KiB pages that should be pre-allocated for page tables.

Selected by graphics drivers that support legacy VGA text mode.

Selected by graphics drivers that can set up a VBE linear-framebuffer mode.

Selected by graphics drivers that can set up a generic linear framebuffer.

Selected by drivers that support to run a blob that implements the Graphics Output Protocol (GOP).

Selected by mainboards / drivers that provide native graphics init within coreboot.

Selected by mainboards / chipsets whose graphics driver can't or shouldn't be disabled.

Selected by mainboards that implement support for `libgfxinit`. Usually this requires a list of ports to be probed for displays.

Some mainboards, such as the Google Link, allow initializing the display without the need of a binary only VGA OPROM. Enabling this option may be faster, but also lacks flexibility in setting modes.

Use the SPARK library `libgfxinit` for the native graphics initialization. This requires an Ada toolchain.

Execute VGA Option ROMs in coreboot if found. This can be used to enable PCI/AGP/PCI-E video cards when not using a SeaBIOS payload.

When using a SeaBIOS payload it runs all option ROMs with much more complete BIOS interrupt services available than coreboot, which some option ROMs require in order to function correctly.

Some platforms (e.g. Intel Braswell and Skylake/Kaby Lake) support to run a GOP blob. This option enables graphics initialization with such a blob.

Select this to not perform any graphics initialization in coreboot. This is useful if the payload (e.g. SeaBIOS) can initialize graphics or if pre-boot graphics are not required.

Execute VGA Option ROMs in coreboot when resuming from S3 suspend.

When using a SeaBIOS payload it runs all option ROMs with much more complete BIOS interrupt services available than coreboot, which some option ROMs require in order to function correctly.

If unsure, say N when using SeaBIOS as payload, Y otherwise.

Always load option ROMs if any are found. The decision to run the ROM is still determined at runtime, but the distinction between loading and not running comes into play for CHROMEOS.

An example where this is required is that VBT (Video BIOS Tables) are needed for the kernel's display driver to know how a piece of hardware is configured to be used.

Always uncondtionally run the option regardless of other policies.

Load Option ROMs stored on PCI/PCIe/AGP VGA devices in coreboot.

If disabled, only Option ROMs stored in CBFS will be executed by coreboot. If you are concerned about security, you might want to disable this option, but it might leave your system in a state of degraded functionality.

When using a SeaBIOS payload it runs all option ROMs with much more complete BIOS interrupt services available than coreboot, which some option ROMs require in order to function correctly.

If unsure, say N when using SeaBIOS as payload, Y otherwise.

If you select this option, PCI Option ROMs will be executed natively on the CPU in real mode. No CPU emulation is involved, so this is the fastest, but also the least secure option. (only works on x86/x64 systems)

If you select this option, the x86emu CPU emulator will be used to execute PCI Option ROMs.

This option prevents Option ROMs from doing dirty tricks with the system (such as installing SMM modules or hypervisors), but it is also significantly slower than the native Option ROM initialization method.

This is the default choice for non-x86 systems.

Per default, YABEL only allows Option ROMs to access the PCI device that they are associated with. However, this causes trouble for some onboard graphics chips whose Option ROM needs to reconfigure the north bridge.

By default, YABEL aborts when the Option ROM tries to write to other devices' config spaces. With this option enabled, the write doesn't follow through, but the Option ROM is allowed to go on. This can create issues such as hanging Option ROMs (if it depends on that other register changing to the written value), so test for impact before using this option.

YABEL requires 1MB memory for its CPU emulation. This memory is normally located at 16MB.

YABEL consists of two parts: It uses x86emu for the CPU emulation and additionally provides a PC system emulation that filters bad device and memory access (such as PCI config space access to other devices than the initialized one).

When choosing this option, x86emu will pass through all hardware accesses to memory and I/O devices to the underlying memory and I/O addresses. While this option prevents Option ROMs from doing dirty tricks with the CPU (such as installing SMM modules or hypervisors), they can still access all devices in the system. Enable this option for a good compromise between security and speed.

Set VESA/native framebuffer mode (needed for bootsplash and graphical framebuffer console)

This option sets the resolution used for the coreboot framebuffer (and bootsplash screen).

This option shows a graphical bootsplash screen. The graphics are loaded from the CBFS file bootsplash.jpg.

You can either specify the location and file name of the image in the 'General' section or add it manually to CBFS, using, for example, cbfstool.

If this option is enabled, coreboot will initialize graphics in legacy VGA text mode or, if a VGA BIOS is used and a VESA mode set, switch to text mode before handing control to a payload.

This option keeps the framebuffer mode set after coreboot finishes execution. If this option is enabled, coreboot will pass a framebuffer entry in its coreboot table and the payload will need a compatible driver.

This option enables a high-resolution, linear framebuffer. If this option is enabled, coreboot will pass a framebuffer entry in its coreboot table and the payload will need a compatible driver.

Detect and enable Common Clock on PCIe links.

Detect and enable ASPM (Active State Power Management) on PCIe links.

Detect and enable Clock Power Management on PCIe.

Detect and enable ASPM on PCIe links.

While coreboot is executing code from ROM, the coreboot resource allocator has not been running yet. Hence PCI devices living behind a bridge are not yet visible to the system.

This option enables static configuration for a single pre-defined PCI bridge function on bus 0.

This config option will override the devicetree settings for PCI Subsystem Vendor ID.

This config option will override the devicetree settings for PCI Subsystem Device ID.

Select this option if you have a VGA BIOS image that you would like to add to your ROM.

You will be able to specify the location and file name of the image later.

The path and filename of the file to use as VGA BIOS.

The comma-separated PCI vendor and device ID that would associate your VGA BIOS to your video card.

Example: 1106,3230

In the above example 1106 is the PCI vendor ID (in hex, but without the "0x" prefix) and 3230 specifies the PCI device ID of the video card (also in hex, without "0x" prefix).

Under GNU/Linux you can run `lspci -nn` to list the IDs of your PCI devices.

Add a VBT data file to CBFS. The VBT describes the integrated GPU and connections, and is needed by the GOP driver integrated into FSP and the OS driver in order to initialize the display.

The path and filename of the VBT binary.

This config option will enable code to override the i2c_transfer routine with a (simple) software emulation of the protocol. This may be useful for debugging or on platforms where a driver for the real I2C controller is not (yet) available. The platform code needs to provide bindings to manually toggle I2C lines.

Enable support for flash based event logging.

This option will have ELOG store a copy of the flash event log in a CBMEM region and export that address in SMBIOS to the OS. This is useful if the ELOG location is not in memory mapped flash, but it means that events added at runtime via the SMI handler will not be reflected in the CBMEM copy of the log.

This interface is compatible with the linux kernel driver available with CONFIG_GOOGLE_GSMI and can be used to write kernel reset/shutdown messages to the event log.

Store a monotonic boot number in CMOS and provide an interface to read the current value and increment the counter. This boot counter will be logged as part of the System Boot event.

This value must be greater than 16 bytes so as not to interfere with the standard RTC region. Requires 8 bytes.

This option allows you to use a so-called USB EHCI Debug device (such as the Ajays NET20DC, AMIDebug RX, or a system using the Linux "EHCI Debug Device gadget" driver found in recent kernel) to retrieve the coreboot debug messages (instead, or in addition to, a serial port).

This feature is NOT supported on all chipsets in coreboot!

It also requires a USB2 controller which supports the EHCI Debug Port capability.

See https://www.coreboot.org/EHCI_Debug_Port for an up-to-date list of supported controllers.

If unsure, say N.

Configuring USB controllers in system-agent binary may cause problems to usbdebug. Disabling this option delays usbdebug to be setup on entry to ramstage.

If unsure, say Y.

Some boards have multiple EHCI controllers with possibly only one having the Debug Port capability on an external USB port.

Mapping of this index to PCI device functions is southbridge specific and mainboard level Kconfig should already provide a working default value here.

Selects which physical USB port usbdebug dongle is connected to. Setting of 0 means to scan possible ports starting from 1.

Intel platforms have hardwired the debug port location and this setting makes no difference there.

Hence, if you select the correct port here, you can speed up your boot time. Which USB port number refers to which actual port on your mainboard (potentially also USB pin headers on your mainboard) is highly board-specific, and you'll likely have to find out by trial-and-error.

Net20DC, BeagleBone Black, Raspberry Pi Zero W

Use this to configure the USB hub on BeagleBone board. Do NOT select this for the BeagleBone Black.

Use this with FT232H usb-to-uart. Configuration is hard-coded to use 8n1, no flow control.

Select baud rate for FT232H in the range 733..12,000,000. Make sure that your receiving side supports the same setting and your connection works with it. Multiples of 115,200 seem to be a good choice, and EHCI debug usually can't saturate more than 576,000.

Use common wrapper to interface CBFS to SPI bootrom.

Select this option if your chipset driver needs to store certain data in the SPI flash.

Which SPI bus the boot device is connected to.

Provide common implementation of the RW boot device that doesn't provide mmap() operations.

Include the common implementation in all stages, including the early ones.

Select this option if you want SPI flash support in SMM.

Select this option if your setup requires to avoid "fast read"s from the SPI flash parts.

Select this option if your chipset driver needs to store certain data in the SPI flash and your SPI flash is made by Adesto Technologies.

Select this option if your chipset driver needs to store certain data in the SPI flash and your SPI flash is made by AMIC.

Select this option if your chipset driver needs to store certain data in the SPI flash and your SPI flash is made by Atmel.

Select this option if your chipset driver needs to store certain data in the SPI flash and your SPI flash is made by EON.

Select this option if your chipset driver needs to store certain data in the SPI flash and your SPI flash is made by Gigadevice.

Select this option if your chipset driver needs to store certain data in the SPI flash and your SPI flash is made by Macronix.

Select this option if your chipset driver needs to store certain data in the SPI flash and your SPI flash is made by Spansion.

Select this option if your chipset driver needs to store certain data in the SPI flash and your SPI flash is made by SST.

Select this option if your chipset driver needs to store certain data in the SPI flash and your SPI flash is made by ST MICRO.

Select this option if your chipset driver needs to store certain data in the SPI flash and your SPI flash is made by Winbond.

Select this option if your SPI flash supports the fast read dual- output command (opcode 0x3b) where the opcode and address are sent to the chip on MOSI and data is received on both MOSI and MISO.

Allows chipset to group write/erase operations under a single volatile group.

Save cached MRC settings

MRC settings are normally written to NVRAM at BS_DEV_ENUMERATE-EXIT. If a platform requires MRC settings written to NVRAM later than normal, select this item. This will cause the write to occur at BS_OS_RESUME_CHECK-ENTRY.

The presence of digitizer is inferred from model number stored in AT24RF chip.

The digitizer is assumed to be present.

The digitizer is assumed to be absent.

Set to "y" when the platform overrides the uart_input_clock_divider routine.

Set to "y" when the platform overrides the uart_platform_refclk routine.

Support for Oxford OXPCIe952 serial port PCIe cards. Currently only devices with the vendor ID 0x1415 and device ID 0xc158 or 0xc11b will work.

Use uart_platform_refclk to specify the input clock value.

Specify zero if the UART is connected to another bus type. For PCI based UARTs, build the value as:

• 1 << 31 - Valid bit, PCI UART in use
• Bus << 20
• Device << 15
• Function << 12

This option enables GIC support, the ARM generic interrupt controller.

This forces a realtek 10ec:8168 card to reset to ensure power state is correct at boot.

This is a string to set the mac address on a Realtek rt8168 card. It must be in the form of "xx:xx:xx:xx:xx:xx", where x is a hexadecimal number for it to be valid. Failing to do so will result in the default macaddress being used.

This is to set a customized LED mode to distinguish 10/100/1000 link and speed status with limited LEDs avaiable on a board. Please refer to RTL811x datasheet section 7.2 Customizable LED Configuration for details. With this flag enabled, the customized_leds variable will be read from devicetree setting.

Enable this option to initialize PS/2 keyboards found connected to the PS/2 port.

Some payloads (eg, filo) require this option. Other payloads (eg, GRUB 2, SeaBIOS, Linux) do not require it. Initializing a PS/2 keyboard can take several hundred milliseconds.

If you know you will only use a payload which does not require this option, then you can say N here to speed up boot time. Otherwise say Y.

Include legacy VGA support code.

LPC TPM driver is enabled!

This can be used to adjust the TPM memory base address. The default is specified by the TCG PC Client Specific TPM Interface Specification 1.2 and should not be changed unless the TPM being used does not conform to TPM TIS 1.2.

This can be used to specify a PIRQ to use instead of SERIRQ, which is needed for SPI TPM interrupt support on x86.

Board has LPC TPM support

Does the code require the Intel Firmware Support Package?

Select this option to add an Intel FSP binary to the resulting coreboot image.

Note: Without this binary, coreboot builds relying on the FSP will not boot

The length in bytes of the microcode update region.

The location (base address) in CBFS that contains the microcode update binary.

The path and filename of the Intel FSP binary for this platform.

The location in CBFS that the FSP is located. This must match the value that is set in the FSP binary. If the FSP needs to be moved, rebase the FSP with Intel's BCT (tool).

Display the user specified product data prior to memory initialization.

If this FSP uses UPD/VPD data regions, select this in the chipset Kconfig.

The chipset can select this to use a generic cache_as_ram.inc file that should be good for all FSP based platforms.

helper functions for intel DDI operations

Set when the SSC reference clock for LVDS runs at a different fre- quency than the general display reference clock.

To be set by northbridge or mainboard Kconfig. For most platforms, there is no choice, i.e. for i945 and gm45 the SSC reference always differs from the display reference clock (i945: 66Mhz SSC vs. 48MHz DREF; gm45: 100MHz SSC vs. 96Mhz DREF), for Nehalem and newer, it's the same frequency for SSC/non-SSC (120MHz). The only, currently supported platform with a choice seems to be Pineview, where the alternative is 100MHz vs. the default 96MHz.

Select this option for Atom-based platforms which use the SWSMISCI register (0xe0) rather than the SWSCI register (0xe8).

Boards with a DVI-I connector share the I2C pins for both analog and digital displays. In that case, the EDID for a VGA display has to be read over the I2C interface of the coupled digital port.

MIPI CSI I2C camera SSDT generator. Generates SSDB and PWDB structures which are used by the Intel kernel drivers.

Select this option to add an Intel FSP binary to the resulting coreboot image.

Note: Without this binary, coreboot builds relying on the FSP will not boot

The path and filename of the Intel FSP binary for this platform.

The location in CBFS that the FSP is located. This must match the value that is set in the FSP binary. If the FSP needs to be moved, rebase the FSP with Intel's BCT (tool).

Enabling this feature will force the MRC data to be cached in NV storage to be used for speeding up boot time on future reboots and/or power cycles.

Enabling this feature will cause MRC data to be cached in NV storage. This can either be used for fast boot, or just because the FSP wants it to be saved.

Use the region "RW_MRC_CACHE" in FMAP instead of "mrc.cache" in CBFS. You must define a region in your FMAP named "RW_MRC_CACHE".

This is the amount of space in NV storage that is reserved for the fast boot data cache storage.

WARNING: Because this area will be erased and re-written, the size should be a full sector of the flash ROM chip and nothing else should be included in CBFS in any sector that the fast boot cache data is in.

This is used to calculate the offset of the MRC data cache in NV Storage for fast boot. If in doubt, leave this set to the default which sets the virtual size equal to the ROM size.

Example: Cougar Canyon 2 has two 8 MB SPI ROMs. When the SPI ROMs are loaded with a 4 MB coreboot image, the virtual ROM size is 8 MB. When the SPI ROMs are loaded with an 8 MB coreboot image, the virtual ROM size is 16 MB.

The chipset can select this to use a generic cache_as_ram.inc file that should be good for all FSP based platforms.

If this FSP uses UPD/VPD data regions, select this in the chipset Kconfig.

When enabled, add identifiers in ACPI and SMBIOS tables to make OS drivers work with certain Intel PCI-e WiFi chipsets.

Enable it when wifi driver uses SAR configuration feature. VPD entry "wifi_sar" is required to support it.

There can be up to 3 optional SAR table sets.

Include FSP 2.0 wrappers and functionality

Add the FSP-M and FSP-S binaries to CBFS. Currently coreboot does not use the FSP-T binary and it is not added.

Display the FSP call entry point and parameters prior to calling FSP and display the status upon return from FSP.

Display the FSP header information when the FSP file is found.

Display the FSP HOBs which are provided for coreboot.

Display the user specified product data prior to memory initialization.

The path and filename of the Intel FSP-M binary for this platform.

The path and filename of the Intel FSP-M binary for this platform.

The path and filename of the Intel FSP-S binary for this platform.

Use FSP APIs to initialize & Tear Down the Cache-As-Ram

Select this value when FSP-M is execute-in-place.

Verify that the HOBs required by coreboot are returned by FSP and that the resource HOBs are in the correct order and position.

Select this option to display Firmware version information.

This is selected by SoC or mainboard to supply their own concept of a version for the memory settings respectively. This allows deployed systems to bump their version number with the same FSP which will trigger a retrain of the memory.

It sets PCI class to IDE compatible native mode, allowing SeaBIOS, FILO etc... to boot from it.

TI TPS65090

VGA driver for qemu emulated vga cards supporting the bochs dispi interface. This includes standard vga, vmware svga and qxl. The default vga (cirrus) is *not* supported, so you have to pick another one explicitly via 'qemu -vga $card'.

SPI TPM driver is enabled!

Board has SPI TPM support

X-Powers AXP902 Power Management Unit

Make AXP209 functionality available in he bootblock.

Parade PS8640 MIPI DSI to eDP Converter

Parade ps8625 display port to lvds bridge

Maxim MAX77686 power regulator

I2C TPM driver is enabled!

Board has an Atmel I2C TPM support

Board has a Cr50 I2C TPM support

Board has a generic I2C TPM support

Enable support for I2C I/O expander PCA9538.

Enable support for external RTC chip RX6110 SA.

Designware I2C support

The i2c ip block's clock.

Enable support for Realtek RTD2132 DisplayPort to LVDS bridge chip.

Select to enable SD/MMC erase oprations

Select to enable SD/MMC write oprations

Display overview of SD/MMC card/device operations

Display details of SD/MMC card/device operations

Display clock speed and bus width settings

Display the operations performed by the SD/MMC controller

Determine if bootblock is able to use ADMA2 or ADMA64

Determine if romstage is able to use ADMA2 or ADMA64

Determine if verstage is able to use ADMA2 or ADMA64

Enabling VBOOT will use vboot to verify the components of the firmware (stages, payload, etc).

VBNV is stored in CMOS

CMOS offset for VbNv data. This value must match cmos.layout in the mainboard directory, minus 14 bytes for the RTC.

Vboot non-volatile storage data will be backed up from CMOS to flash and restored from flash if the CMOS is invalid due to power loss.

VBNV is stored in EC

VBNV is stored in flash storage

Firmware verification happens during the end of or right after the bootblock. This implies that a static VBOOT2_WORK() buffer must be allocated in memlayout.

Firmware verification happens during the end of romstage (after memory initialization). This implies that vboot working data is allocated in CBMEM.

Enabling VBOOT_MOCK_SECDATA will mock secdata for the firmware verification to avoid access to a secdata storage (typically TPM). All operations for a secdata storage will be successful. This option can be used during development when a TPM is not present or broken. THIS SHOULD NOT BE LEFT ON FOR PRODUCTION DEVICES.

When this option is enabled, the Chrome OS device leaves the developer mode as soon as recovery request is detected. This is handy on embedded devices with limited input capabilities.

If this option is set, vboot verification runs in a standalone stage that is loaded from the bootblock and exits into romstage. If it is not set, the verification code is linked directly into the bootblock or the romstage and runs as part of that stage (cf. related options VBOOT_STARTS_IN_BOOTBLOCK/_ROMSTAGE and VBOOT_RETURN_FROM_VERSTAGE).

If this is set, the verstage returns back to the calling stage instead of exiting to the succeeding stage so that the verstage space can be reused by the succeeding stage. This is useful if a RAM space is too small to fit both the verstage and the succeeding stage.

This option ensures that the recovery request is not lost because of reboots caused after vboot verification is run. e.g. reboots caused by FSP components on Intel platforms.

Set this option to indicate to vboot that this platform will skip its display initialization on a normal (non-recovery, non-developer) boot. Vboot calls this "oprom matters" because on x86 devices this traditionally meant that the video option ROM will not be loaded, but it works functionally the same for other platforms that can skip their native display initialization code instead.

Set this option to indicate to vboot that recovery data hash space is present in TPM.

EC software sync is a mechanism where the AP helps the EC verify its firmware similar to how vboot verifies the main system firmware. This option selects whether vboot should support EC software sync.

Whether the EC (or PD) is slow to update and needs to display a screen that informs the user the update is happening.

CrosEC can support EFS: Early Firmware Selection. If it's enabled, software sync need to also support it. This setting tells vboot to perform EFS software sync.

Whether this platform has a physical developer switch. Note that this disables virtual dev switch functionality (through secdata). Operation where both a physical pin and the virtual switch get sampled is not supported by coreboot.

Whether this platform has a physical recovery switch.

Whether this platform has a lid switch. If it does, vboot will not decrement try counters for boot failures if the lid is closed.

When this option is enabled, the firmware provides the ability to signal the application the need for factory reset (a.k.a. wipe out) of the device

This is the first part of the FWID written to various regions of a vboot firmware image to identify its version.

This is the second part of the FWID written to various regions of a vboot firmware image to identify its version.

Enable weak functions for get_write_protect_state and get_recovery_mode_switch in order to proceed with refactoring of the vboot2 code base. Later on this code is removed and replaced by interfaces.

Add a space delimited list of filenames that should only be in the RO section.

Power off machine while waiting for CR50 update to take effect.

Enable this option to enable TPM 1.0 - 1.2 support in coreboot.

If unsure, say N.

Enable this option to enable TPM 2.0 support in coreboot.

If unsure, say N.

Deactivate TPM by issuing deactivate command.

This option enables additional TPM related debug messages.

Certain TPMs seem to need some delay when reading response to work around a race-condition-related issue, possibly caused by ill-programmed TPM firmware.

Use ACPI SATA port generator.

Provide common definitions for Intel hardware PM1_CNT register sleep values.

Provide common definitions for AMD hardware PM1_CNT register sleep values.

Inform system if SPI is memory-mapped or not.

Indicate that the platform has writable boot device support.

Use console during the bootblock if supported

Use console during the postcar if supported

When selected only the BSP CPU will output to early console.

Console drivers have unpredictable behaviour if multiple threads attempt to share the same resources without a spinlock.

If unsure, say Y.

Send coreboot debug output to a serial port.

The type of serial port driver selected based on your configuration is shown on the following menu line. Supporting multiple different types of UARTs in one build is not supported.

Select an I/O port to use for serial console: 0 = 0x3f8, 1 = 0x2f8, 2 = 0x3e8, 3 = 0x2e8

Map the COM port number to the respective I/O port.

Set to "y" when the platform overrides the baudrate by providing a get_uart_baudrate routine.

Set serial port Baud rate to 921600.

Set serial port Baud rate to 460800.

Set serial port Baud rate to 230400.

Set serial port Baud rate to 115200.

Set serial port Baud rate to 57600.

Set serial port Baud rate to 38400.

Set serial port Baud rate to 19200.

Set serial port Baud rate to 9600.

Map the Baud rates to an integer.

Send coreboot debug output through speaker

Send coreboot debug output to USB.

Configuration for USB hardware is under menu Generic Drivers.

If not selected, the last adapter found will be used.

Send coreboot debug output to a Ethernet console, it works same way as Linux netconsole, packets are received to UDP port 6666 on IP/MAC specified with options bellow. Use following netcat command: nc -u -l -p 6666

Type in either MAC address of logging system or MAC address of the router.

This is IP address of the system running for example netcat command to dump the packets.

This is the IP of the coreboot system

This is the IO port address for the IO port on the card, please select some non-conflicting region, 32 bytes of IO spaces will be used (and align on 32 bytes boundary, qemu needs broader align)

Enable this to save the console output in a CBMEM buffer. This would allow to see coreboot console output from Linux space.

Space allocated for console output storage in CBMEM. The default value (128K or 0x20000 bytes) is large enough to accommodate even the BIOS_SPEW level.

Enable this to have CBMEM console buffer contents dumped on the serial output in case serial console is disabled and the device resets itself while trying to boot the payload.

Send coreboot debug output to the SPI Flash in the FMAP CONSOLE area

This option can cause premature wear on the SPI flash and should not be used as a normal means of debugging. It is only to be enabled and used when porting a new motherboard which has no other console available (no UART, no POST, no cbmem access(non bootable)). Since a non bootable machine will require the use of an external SPI Flash programmer, the developer can grab the console log at the same time.

The flash console will not be erased on reboot, so once it is full, the flashconsole driver will stop writing to it. This is to avoid wear on the flash, and to avoid erasing sectors (which may freeze the SPI controller on skylake).

The 'CONSOLE' area can be extracted from the FMAP with : cbfstool rom.bin read -r CONSOLE -f console.log

Space allocated for console output storage in FMAP. The default value (128K or 0x20000 bytes) is large enough to accommodate even the BIOS_SPEW level.

Send coreboot debug output to QEMU's isa-debugcon device:

qemu-system-x86_64 \ -chardev file,id=debugcon,path=/dir/file.log \ -device isa-debugcon,iobase=0x402,chardev=debugcon

Enable support for the debug console on the Dediprog EM100Pro. This is currently working only in ramstage due to how the spi drivers are written.

Set to "y" when the platform overrides the loglevel by providing a get_console_loglevel routine.

Way too many details.

Debug-level messages.

Informational messages.

Normal but significant conditions.

Warning conditions.

Error conditions.

Critical conditions.

Action must be taken immediately.

System is unusable.

Map the log level config names to an integer.

If enabled, coreboot will store post codes in CMOS and switch between two offsets on each boot so the last post code in the previous boot can be retrieved. This uses 3 bytes of CMOS.

If CMOS_POST is enabled then an offset into CMOS must be provided. If CONFIG_HAVE_OPTION_TABLE is enabled then it will use the value defined in the mainboard option table.

This will enable extra logging of work that happens between post codes into CMOS for debug. This uses an additional 8 bytes of CMOS.

If enabled, coreboot will additionally print POST codes (which are usually displayed using a so-called "POST card" ISA/PCI/PCI-E device) on the debug console.

If enabled, POST codes will be written to an IO port.

POST codes on x86 are typically written to the LPC bus on port 0x80. However, it may be desirable to change the port number depending on the presence of coprocessors/microcontrollers or if the platform does not support IO in the conventional x86 manner.

Some chipsets require that the routing for the port 80h POST code be configured before any POST codes are sent out. This can be done in the boot block, but there are a couple of POST codes that go out before the chipset's bootblock initialization can happen. This option suppresses those POST codes.

On S3 resume path, backup low memory from RAMBASE..RAMTOP in CBMEM.

This option indicates that when a system resumes it takes the same path as a regular boot. e.g. an x86 system runs from the reset vector at 0xfffffff0 on both resume and warm/cold boot.

This variable specifies whether a given board has a hard_reset function, no matter if it's provided by board code or chipset code.

This should be enabled on certain plaforms, such as the AMD SR565x, that cannot handle concurrent CBFS accesses from multiple APs during early startup.

The board/chipset provides a monotonic timer.

The board/chipset uses a generic udelay function utilizing the monotonic timer.

Provide a timer queue for performing time-based callbacks.

Cooperative multitasking allows callbacks to be multiplexed on the main thread of ramstage. With this enabled it allows for multiple execution paths to take place when they have udelay() calls within their code.

How many execution threads to cooperatively multitask with.

This variable specifies whether a given board has a cmos.layout file containing NVRAM/CMOS bit definitions. It defaults to 'n' but can be selected in mainboard/*/Kconfig.

Enable Unified Memory Architecture for graphics.

This variable specifies whether a given board has ACPI table support. It is usually set in mainboard/*/Kconfig.

This variable specifies whether a given board has MP table support. It is usually set in mainboard/*/Kconfig. Whether or not the MP table is actually generated by coreboot is configurable by the user via GENERATE_MP_TABLE.

This variable specifies whether a given board has PIRQ table support. It is usually set in mainboard/*/Kconfig. Whether or not the PIRQ table is actually generated by coreboot is configurable by the user via GENERATE_PIRQ_TABLE.

This variable specifies the number of PIRQ interrupt links which are routable. On most chipsets, this is 4, INTA through INTD. Some chipsets offer more than four links, commonly up to INTH. They may also have a separate link for ATA or IOAPIC interrupts. When the PIRQ table specifies links greater than 4, pirq_route_irqs will not function properly, unless this variable is correctly set.

Build support for NHLT (non HD Audio) ACPI table generation.

Generate an MP table (conforming to the Intel MultiProcessor specification 1.4) for this board.

If unsure, say Y.

Generate a PIRQ table for this board.

If unsure, say Y.

Generate SMBIOS tables for this board.

If unsure, say Y.

The Serial Number to store in SMBIOS structures.

The Version Number to store in SMBIOS structures.

Override the default Manufacturer stored in SMBIOS structures.

Override the default Product name stored in SMBIOS structures.

System Enclosure or Chassis Types as defined in SMBIOS specification. The default value is SMBIOS_ENCLOSURE_DESKTOP (0x03) or SMBIOS_ENCLOSURE_LAPTOP (0x09) if SYSTEM_TYPE_LAPTOP is set.

Select this option if you want to create an "empty" coreboot ROM image for a certain mainboard, i.e. a coreboot ROM image which does not yet contain a payload.

For such an image to be useful, you have to use 'cbfstool' to add a payload to the ROM image later.

Select this option if you have a payload image (an ELF file) which coreboot should run as soon as the basic hardware initialization is completed.

You will be able to specify the location and file name of the payload image later.

Select this option if you want to set bayou as your primary payload.

Select this option if you want to build a coreboot image with a U-Boot payload.

See https://coreboot.org/Payloads and U-Boot's documentation at http://git.denx.de/?p=u-boot.git;a=blob;f=doc/README.x86 for more information.

Select this option if you want to build a coreboot image with a SeaBIOS payload. If you don't know what this is about, just leave it enabled.

See https://coreboot.org/Payloads for more information.

Select this option if you want to build a coreboot image with a FILO payload. If you don't know what this is about, just leave it enabled.

See https://coreboot.org/Payloads for more information.

Select this option if you have a Linux bzImage which coreboot should run as soon as the basic hardware initialization is completed.

You will be able to specify the location and file name of the payload image later.

Select this option if you want to build a coreboot image with a Tianocore payload. If you don't know what this is about, just leave it enabled.

See https://coreboot.org/Payloads for more information.

Select this option if you want to build a coreboot image with a GRUB2 payload. If you don't know what this is about, just leave it enabled.

See https://coreboot.org/Payloads for more information.

Select this option if you want to build a coreboot image with a depthcharge payload.