plat/allwinner/common/arisc_off.S - tf-a-mtk - Git at Google

 # turn_off_core.S
 #
 # Copyright (c) 2018, Andre Przywara <osp@andrep.de>
 # SPDX-License-Identifier: BSD-3-Clause
 #
 # OpenRISC assembly to turn off an ARM core on an Allwinner SoC from
 # the arisc management controller.
 # Generate a binary representation with:
 # $ or1k-elf-as -c -o turn_off_core.o turn_off_core.S
 # $ or1k-elf-objcopy -O binary --reverse-bytes=4 turn_off_core.o \
 #   turn_off_core.bin
 # The encoded instructions go into an array defined in
 # plat/allwinner/sun50i_*/include/core_off_arisc.h, to be handed off to
 # the arisc processor.
 #
 # This routine is meant to be called directly from arisc reset (put the
 # start address in the reset vector), to be actually triggered by that
 # very ARM core to be turned off.
 # It expects the core number presented as a mask in the upper half of
 # r3, so to be patched in the lower 16 bits of the first instruction,
 # overwriting the 0 in this code here.
 # The code will do the following:
 # - Read the C_CPU_STATUS register, which contains the status of the WFI
 #   lines of each of the four A53 cores.
 # - Loop until the core in question reaches WFI.
 # - Using that mask, activate the core output clamps by setting the
 #   respective core bit in CPUX_PWROFF_GATING_REG (0x1f01500).
 #   Note that the clamp for core 0 covers more than just the core, activating
 #   it hangs the whole system. So we skip this step for core 0.
 # - Using the negated mask, assert the core's reset line by clearing the
 #   respective bit in C_RST_CTRL (0x1f01c30).
 # - Finally turn off the core's power switch by writing 0xff to the
 #   respective CPUx_PWR_SWITCH_REG (0x1f01540 ff.)
 # - Assert the arisc's own reset to end execution.
 #   This also signals other arisc users that the chip is free again.
 # So in C this would look like:
 #	while (!(readl(0x1700030) & (1U << core_nr)))
 #		;
 #	if (core_nr != 0)
 #		writel(readl(0x1f01500) | (1U << core_nr), 0x1f01500);
 #	writel(readl(0x1f01c30) & ~(1U << core_nr), 0x1f01c30);
 #	writel(0xff, 0x1f01540 + (core_nr * 4));
 # (using A64/H5 addresses)

 .text
 _start:
 	l.movhi	r3, 0				# FIXUP! with core mask
 	l.movhi r0, 0				# clear r0
 	l.movhi	r13, 0x170			# r13: CPU_CFG_BASE=0x01700000
 wait_wfi:
 	l.lwz	r5, 0x30(r13)			# load C_CPU_STATUS
 	l.and	r5, r5, r3			# mask requested core
 	l.sfeq	r5, r0				# is it not yet in WFI?
 	l.bf	wait_wfi			# try again

 	l.srli	r6, r3, 16			# move mask to lower 16 bits
 	l.sfeqi	r6, 1				# core 0 is special
 	l.bf	1f				# don't touch the bit for core 0
 	l.movhi	r13, 0x1f0			# address of R_CPUCFG (delay)
 	l.lwz	r5, 0x1500(r13)			# core output clamps
 	l.or	r5, r5, r6			# set bit to ...
 	l.sw	0x1500(r13), r5			# ... activate for our core

 1:	l.lwz	r5, 0x1c30(r13)			# CPU power-on reset
 	l.xori	r6, r6, -1			# negate core mask
 	l.and	r5, r5, r6			# clear bit to ...
 	l.sw	0x1c30(r13), r5			# ... assert for our core

 	l.ff1	r6, r3				# get core number from high mask
 	l.addi	r6, r6, -17			# convert to 0-3
 	l.slli	r6, r6, 2			# r5: core number*4 (0-12)
 	l.add	r6, r6, r13			# add to base address
 	l.ori	r5, r0, 0xff			# 0xff means all switches off
 	l.sw	0x1540(r6), r5			# core power switch registers

 reset:	l.sw	0x1c00(r13),r0			# pull down our own reset line

 	l.j	reset				# just in case ....
 	l.nop	0x0				# (delay slot)

 # same as above, but with the MMIO addresses matching the H6 SoC
 _start_h6:
 	l.movhi	r3, 0				# FIXUP! with core mask
 	l.movhi r0, 0				# clear r0
 	l.movhi	r13, 0x901			# r13: CPU_CFG_BASE=0x09010000
 1:
 	l.lwz	r5, 0x80(r13)			# load C_CPU_STATUS
 	l.and	r5, r5, r3			# mask requested core
 	l.sfeq	r5, r0				# is it not yet in WFI?
 	l.bf	1b				# try again

 	l.srli	r6, r3, 16			# move mask to lower 16 bits(ds)
 	l.sfeqi	r6, 1				# core 0 is special
 	l.bf	1f				# don't touch the bit for core 0
 	l.movhi	r13, 0x700			# address of R_CPUCFG (ds)
 	l.lwz	r5, 0x0444(r13)			# core output clamps
 	l.or	r5, r5, r6			# set bit to ...
 	l.sw	0x0444(r13), r5			# ... activate for our core

 1:	l.lwz	r5, 0x0440(r13)			# CPU power-on reset
 	l.xori	r6, r6, -1			# negate core mask
 	l.and	r5, r5, r6			# clear bit to ...
 	l.sw	0x0440(r13), r5			# ... assert for our core

 	l.ff1	r6, r3				# get core number from high mask
 	l.addi	r6, r6, -17			# convert to 0-3
 	l.slli	r6, r6, 2			# r5: core number*4 (0-12)
 	l.add	r6, r6, r13			# add to base address
 	l.ori	r5, r0, 0xff			# 0xff means all switches off
 	l.sw	0x0450(r6), r5			# core power switch registers

 1:	l.sw	0x0400(r13),r0			# pull down our own reset line

 	l.j	1b				# just in case ...
 	l.nop	0x0				# (delay slot)
	# turn_off_core.S
	#
	# Copyright (c) 2018, Andre Przywara <osp@andrep.de>
	# SPDX-License-Identifier: BSD-3-Clause
	#
	# OpenRISC assembly to turn off an ARM core on an Allwinner SoC from
	# the arisc management controller.
	# Generate a binary representation with:
	# $ or1k-elf-as -c -o turn_off_core.o turn_off_core.S
	# $ or1k-elf-objcopy -O binary --reverse-bytes=4 turn_off_core.o \
	# turn_off_core.bin
	# The encoded instructions go into an array defined in
	# plat/allwinner/sun50i_*/include/core_off_arisc.h, to be handed off to
	# the arisc processor.
	#
	# This routine is meant to be called directly from arisc reset (put the
	# start address in the reset vector), to be actually triggered by that
	# very ARM core to be turned off.
	# It expects the core number presented as a mask in the upper half of
	# r3, so to be patched in the lower 16 bits of the first instruction,
	# overwriting the 0 in this code here.
	# The code will do the following:
	# - Read the C_CPU_STATUS register, which contains the status of the WFI
	# lines of each of the four A53 cores.
	# - Loop until the core in question reaches WFI.
	# - Using that mask, activate the core output clamps by setting the
	# respective core bit in CPUX_PWROFF_GATING_REG (0x1f01500).
	# Note that the clamp for core 0 covers more than just the core, activating
	# it hangs the whole system. So we skip this step for core 0.
	# - Using the negated mask, assert the core's reset line by clearing the
	# respective bit in C_RST_CTRL (0x1f01c30).
	# - Finally turn off the core's power switch by writing 0xff to the
	# respective CPUx_PWR_SWITCH_REG (0x1f01540 ff.)
	# - Assert the arisc's own reset to end execution.
	# This also signals other arisc users that the chip is free again.
	# So in C this would look like:
	# while (!(readl(0x1700030) & (1U << core_nr)))
	# ;
	# if (core_nr != 0)
	# writel(readl(0x1f01500) \| (1U << core_nr), 0x1f01500);
	# writel(readl(0x1f01c30) & ~(1U << core_nr), 0x1f01c30);
	# writel(0xff, 0x1f01540 + (core_nr * 4));
	# (using A64/H5 addresses)

	.text
	_start:
	l.movhi r3, 0 # FIXUP! with core mask
	l.movhi r0, 0 # clear r0
	l.movhi r13, 0x170 # r13: CPU_CFG_BASE=0x01700000
	wait_wfi:
	l.lwz r5, 0x30(r13) # load C_CPU_STATUS
	l.and r5, r5, r3 # mask requested core
	l.sfeq r5, r0 # is it not yet in WFI?
	l.bf wait_wfi # try again

	l.srli r6, r3, 16 # move mask to lower 16 bits
	l.sfeqi r6, 1 # core 0 is special
	l.bf 1f # don't touch the bit for core 0
	l.movhi r13, 0x1f0 # address of R_CPUCFG (delay)
	l.lwz r5, 0x1500(r13) # core output clamps
	l.or r5, r5, r6 # set bit to ...
	l.sw 0x1500(r13), r5 # ... activate for our core

	1: l.lwz r5, 0x1c30(r13) # CPU power-on reset
	l.xori r6, r6, -1 # negate core mask
	l.and r5, r5, r6 # clear bit to ...
	l.sw 0x1c30(r13), r5 # ... assert for our core

	l.ff1 r6, r3 # get core number from high mask
	l.addi r6, r6, -17 # convert to 0-3
	l.slli r6, r6, 2 # r5: core number*4 (0-12)
	l.add r6, r6, r13 # add to base address
	l.ori r5, r0, 0xff # 0xff means all switches off
	l.sw 0x1540(r6), r5 # core power switch registers

	reset: l.sw 0x1c00(r13),r0 # pull down our own reset line

	l.j reset # just in case ....
	l.nop 0x0 # (delay slot)

	# same as above, but with the MMIO addresses matching the H6 SoC
	_start_h6:
	l.movhi r3, 0 # FIXUP! with core mask
	l.movhi r0, 0 # clear r0
	l.movhi r13, 0x901 # r13: CPU_CFG_BASE=0x09010000
	1:
	l.lwz r5, 0x80(r13) # load C_CPU_STATUS
	l.and r5, r5, r3 # mask requested core
	l.sfeq r5, r0 # is it not yet in WFI?
	l.bf 1b # try again

	l.srli r6, r3, 16 # move mask to lower 16 bits(ds)
	l.sfeqi r6, 1 # core 0 is special
	l.bf 1f # don't touch the bit for core 0
	l.movhi r13, 0x700 # address of R_CPUCFG (ds)
	l.lwz r5, 0x0444(r13) # core output clamps
	l.or r5, r5, r6 # set bit to ...
	l.sw 0x0444(r13), r5 # ... activate for our core

	1: l.lwz r5, 0x0440(r13) # CPU power-on reset
	l.xori r6, r6, -1 # negate core mask
	l.and r5, r5, r6 # clear bit to ...
	l.sw 0x0440(r13), r5 # ... assert for our core

	l.ff1 r6, r3 # get core number from high mask
	l.addi r6, r6, -17 # convert to 0-3
	l.slli r6, r6, 2 # r5: core number*4 (0-12)
	l.add r6, r6, r13 # add to base address
	l.ori r5, r0, 0xff # 0xff means all switches off
	l.sw 0x0450(r6), r5 # core power switch registers

	1: l.sw 0x0400(r13),r0 # pull down our own reset line

	l.j 1b # just in case ...
	l.nop 0x0 # (delay slot)