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RISC-V architecture documentation
This section contains documentation about coreboot on RISC-V architecture.
Mode usage
All stages run in M mode.
Payloads have a choice of managing M mode activity: they can control everything or nothing.
Payloads run from the romstage (i.e. rampayloads) are started in M mode. The payload must, for example, prepare and install its own SBI.
Payloads run from the ramstage are started in S mode, and trap delegation will have been done. These payloads rely on the SBI and can not replace it.
Stage handoff protocol
On entry to a stage or payload (including SELF payloads),
- all harts are running.
- A0 is the hart ID.
- A1 is the pointer to the Flattened Device Tree (FDT).
- A2 contains the additional program calling argument:
- cbmem_top for ramstage
- the address of the payload for opensbi
Additional payload handoff requirements
The location of cbmem should be placed in a node in the FDT.
OpenSBI
In case the payload doesn't install it's own SBI, like the RISCV-PK does, OpenSBI can be used instead. It's loaded into RAM after coreboot has finished loading the payload. coreboot then will jump to OpenSBI providing a pointer to the real payload, which OpenSBI will jump to once the SBI is installed.
Besides providing SBI it also sets protected memory regions and provides a platform independent console.
The OpenSBI code is always run in M mode.
Trap delegation
Traps are delegated to the payload.
SMP within a stage
At the beginning of each stage, all harts save 0 are spinning in a loop on a semaphore. At the end of the stage harts 1..max are released by changing the semaphore.
A possible way to do this is to have a pointer to a struct containing variables, e.g.
struct blocker {
void (*fn)(); // never returns
}
The hart blocks until fn is non-null, and then calls it. If fn returns, we will panic if possible, but behavior is largely undefined.
Only hart 0 runs through most of the code in each stage.