106 lines
3.0 KiB
Markdown
106 lines
3.0 KiB
Markdown
# coreboot architecture
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## Overview
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![][architecture]
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[architecture]: comparision_coreboot_uefi.svg
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## Stages
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coreboot consists of multiple stages that are compiled as separate binaries and
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are inserted into the CBFS with custom compression. The bootblock usually doesn't
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have compression while the ramstage and payload are compressed with LZMA.
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Each stage loads the next stage at given address (possibly decompressing it).
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Some stages are relocatable and can be placed anywhere in DRAM. Those stages are
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usually cached in CBMEM for faster loading times on ACPI S3 resume.
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Supported stage compressions:
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* none
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* LZ4
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* LZMA
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## bootblock
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The bootblock is the first stage executed after CPU reset. It is written in
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assembly language and its main task is to set up everything for a C-environment:
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Common tasks:
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* Cache-As-RAM for heap and stack
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* Set stack pointer
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* Clear memory for BSS
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* Decompress and load the next stage
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On x86 platforms that includes:
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* Microcode updates
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* Timer init
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* Switching from 16-bit real-mode to 32-bit protected mode
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The bootblock loads the romstage or the verstage if verified boot is enabled.
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### Cache-As-Ram
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The *Cache-As-Ram*, also called Non-Eviction mode, or *CAR* allows to use the
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CPU cache like regular SRAM. This is particullary usefull for high level
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languages like `C`, which need RAM for heap and stack.
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The CAR needs to be activated using vendor specific CPU instructions.
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The following stages run when Cache-As-Ram is active:
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* bootblock
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* romstage
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* verstage
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* postcar
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## verstage
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The verstage is where the root-of-trust starts. It's assumed that
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it cannot be overwritten in-field (together with the public key) and
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it starts at the very beginning of the boot process.
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The verstage installs a hook to verify a file before it's loaded from
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CBFS or a partition before it's accessed.
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The verified boot mechanism allows trusted in-field firmware updates
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combined with a fail-safe recovery mode.
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## romstage
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The romstage initializes the DRAM and prepares everything for device init.
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Common tasks:
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* Early device init
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* DRAM init
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## postcar
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To leave the CAR setup and run code from regular DRAM the postcar-stage tears
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down CAR and loads the ramstage. Compared to other stages it's minimal in size.
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## ramstage
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The ramstage does the main device init:
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* PCI device init
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* On-chip device init
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* TPM init (if not done by verstage)
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* Graphics init (optional)
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* CPU init (like set up SMM)
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After initialization tables are written to inform the payload or operating system
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about the current hardware existance and state. That includes:
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* ACPI tables (x86 specific)
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* SMBIOS tables (x86 specific)
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* coreboot tables
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* devicetree updates (ARM specific)
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It also does hardware and firmware lockdown:
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* Write-protection of boot media
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* Lock security related registers
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* Lock SMM mode (x86 specific)
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## payload
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The payload is the software that is run after coreboot is done. It resides in
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the CBFS and there's no possibility to choose it at runtime.
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For more details have a look at [payloads](../payloads.md).
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