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https://github.com/AsahiLinux/u-boot
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078332cee3
The AM642 SoCs use the Main R5FSS0 as a boot processor, and runs the R5 SPL that performs the initialization of the System Controller processor and starting the Arm Trusted Firmware (ATF) on the Arm Cortex A53 cluster. The Core0 serves as this boot processor and is parked in WFE after all the initialization. Core1 does not directly participate in the boot flow, and is simply parked in a WFI. Power down these R5 cores (and the associated RTI timer resources that were indirectly powered up) after starting up ATF on A53 by using the appropriate SYSFW API in release_resources_for_core_shutdown(). This allows these Main R5F cores to be further controlled from the A53 to run regular applications. Signed-off-by: Suman Anna <s-anna@ti.com> Signed-off-by: Dave Gerlach <d-gerlach@ti.com>
283 lines
6.6 KiB
C
283 lines
6.6 KiB
C
// SPDX-License-Identifier: GPL-2.0
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/*
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* AM642: SoC specific initialization
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*
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* Copyright (C) 2020-2021 Texas Instruments Incorporated - https://www.ti.com/
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* Keerthy <j-keerthy@ti.com>
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* Dave Gerlach <d-gerlach@ti.com>
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*/
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#include <common.h>
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#include <spl.h>
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#include <asm/io.h>
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#include <asm/arch/hardware.h>
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#include <asm/arch/sysfw-loader.h>
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#include <asm/arch/sys_proto.h>
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#include "common.h"
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#include <asm/arch/sys_proto.h>
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#include <linux/soc/ti/ti_sci_protocol.h>
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#include <dm.h>
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#include <dm/uclass-internal.h>
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#include <dm/pinctrl.h>
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#include <mmc.h>
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#if defined(CONFIG_SPL_BUILD)
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static void ctrl_mmr_unlock(void)
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{
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/* Unlock all PADCFG_MMR1 module registers */
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mmr_unlock(PADCFG_MMR1_BASE, 1);
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/* Unlock all CTRL_MMR0 module registers */
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mmr_unlock(CTRL_MMR0_BASE, 0);
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mmr_unlock(CTRL_MMR0_BASE, 1);
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mmr_unlock(CTRL_MMR0_BASE, 2);
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mmr_unlock(CTRL_MMR0_BASE, 3);
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mmr_unlock(CTRL_MMR0_BASE, 5);
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mmr_unlock(CTRL_MMR0_BASE, 6);
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}
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/*
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* This uninitialized global variable would normal end up in the .bss section,
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* but the .bss is cleared between writing and reading this variable, so move
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* it to the .data section.
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*/
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u32 bootindex __section(".data");
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static struct rom_extended_boot_data bootdata __section(.data);
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static void store_boot_info_from_rom(void)
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{
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bootindex = *(u32 *)(CONFIG_SYS_K3_BOOT_PARAM_TABLE_INDEX);
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memcpy(&bootdata, (uintptr_t *)ROM_ENTENDED_BOOT_DATA_INFO,
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sizeof(struct rom_extended_boot_data));
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}
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#if defined(CONFIG_K3_LOAD_SYSFW) && CONFIG_IS_ENABLED(DM_MMC)
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void k3_mmc_stop_clock(void)
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{
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if (spl_boot_device() == BOOT_DEVICE_MMC1) {
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struct mmc *mmc = find_mmc_device(0);
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if (!mmc)
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return;
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mmc->saved_clock = mmc->clock;
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mmc_set_clock(mmc, 0, true);
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}
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}
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void k3_mmc_restart_clock(void)
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{
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if (spl_boot_device() == BOOT_DEVICE_MMC1) {
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struct mmc *mmc = find_mmc_device(0);
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if (!mmc)
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return;
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mmc_set_clock(mmc, mmc->saved_clock, false);
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}
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}
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#else
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void k3_mmc_stop_clock(void) {}
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void k3_mmc_restart_clock(void) {}
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#endif
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void board_init_f(ulong dummy)
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{
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#if defined(CONFIG_K3_LOAD_SYSFW)
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struct udevice *dev;
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int ret;
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#endif
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#if defined(CONFIG_CPU_V7R)
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setup_k3_mpu_regions();
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#endif
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/*
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* Cannot delay this further as there is a chance that
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* K3_BOOT_PARAM_TABLE_INDEX can be over written by SPL MALLOC section.
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*/
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store_boot_info_from_rom();
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ctrl_mmr_unlock();
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/* Init DM early */
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spl_early_init();
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preloader_console_init();
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#if defined(CONFIG_K3_LOAD_SYSFW)
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/*
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* Process pinctrl for serial3 a.k.a. MAIN UART1 module and continue
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* regardless of the result of pinctrl. Do this without probing the
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* device, but instead by searching the device that would request the
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* given sequence number if probed. The UART will be used by the system
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* firmware (SYSFW) image for various purposes and SYSFW depends on us
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* to initialize its pin settings.
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*/
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ret = uclass_find_device_by_seq(UCLASS_SERIAL, 3, &dev);
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if (!ret)
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pinctrl_select_state(dev, "default");
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/*
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* Load, start up, and configure system controller firmware.
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* This will determine whether or not ROM has already loaded
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* system firmware and if so, will only perform needed config
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* and not attempt to load firmware again.
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*/
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k3_sysfw_loader(is_rom_loaded_sysfw(&bootdata), k3_mmc_stop_clock,
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k3_mmc_restart_clock);
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#endif
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/* Output System Firmware version info */
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k3_sysfw_print_ver();
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}
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u32 spl_boot_mode(const u32 boot_device)
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{
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switch (boot_device) {
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case BOOT_DEVICE_MMC1:
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return MMCSD_MODE_EMMCBOOT;
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case BOOT_DEVICE_MMC2:
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return MMCSD_MODE_FS;
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default:
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return MMCSD_MODE_RAW;
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}
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}
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static u32 __get_backup_bootmedia(u32 main_devstat)
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{
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u32 bkup_bootmode =
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(main_devstat & MAIN_DEVSTAT_BACKUP_BOOTMODE_MASK) >>
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MAIN_DEVSTAT_BACKUP_BOOTMODE_SHIFT;
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u32 bkup_bootmode_cfg =
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(main_devstat & MAIN_DEVSTAT_BACKUP_BOOTMODE_CFG_MASK) >>
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MAIN_DEVSTAT_BACKUP_BOOTMODE_CFG_SHIFT;
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switch (bkup_bootmode) {
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case BACKUP_BOOT_DEVICE_UART:
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return BOOT_DEVICE_UART;
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case BACKUP_BOOT_DEVICE_USB:
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return BOOT_DEVICE_USB;
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case BACKUP_BOOT_DEVICE_ETHERNET:
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return BOOT_DEVICE_ETHERNET;
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case BACKUP_BOOT_DEVICE_MMC:
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if (bkup_bootmode_cfg)
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return BOOT_DEVICE_MMC2;
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return BOOT_DEVICE_MMC1;
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case BACKUP_BOOT_DEVICE_SPI:
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return BOOT_DEVICE_SPI;
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case BACKUP_BOOT_DEVICE_I2C:
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return BOOT_DEVICE_I2C;
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};
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return BOOT_DEVICE_RAM;
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}
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static u32 __get_primary_bootmedia(u32 main_devstat)
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{
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u32 bootmode = (main_devstat & MAIN_DEVSTAT_PRIMARY_BOOTMODE_MASK) >>
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MAIN_DEVSTAT_PRIMARY_BOOTMODE_SHIFT;
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u32 bootmode_cfg =
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(main_devstat & MAIN_DEVSTAT_PRIMARY_BOOTMODE_CFG_MASK) >>
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MAIN_DEVSTAT_PRIMARY_BOOTMODE_CFG_SHIFT;
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switch (bootmode) {
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case BOOT_DEVICE_OSPI:
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fallthrough;
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case BOOT_DEVICE_QSPI:
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fallthrough;
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case BOOT_DEVICE_XSPI:
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fallthrough;
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case BOOT_DEVICE_SPI:
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return BOOT_DEVICE_SPI;
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case BOOT_DEVICE_ETHERNET_RGMII:
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fallthrough;
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case BOOT_DEVICE_ETHERNET_RMII:
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return BOOT_DEVICE_ETHERNET;
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case BOOT_DEVICE_EMMC:
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return BOOT_DEVICE_MMC1;
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case BOOT_DEVICE_MMC:
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if ((bootmode_cfg & MAIN_DEVSTAT_PRIMARY_MMC_PORT_MASK) >>
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MAIN_DEVSTAT_PRIMARY_MMC_PORT_SHIFT)
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return BOOT_DEVICE_MMC2;
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return BOOT_DEVICE_MMC1;
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case BOOT_DEVICE_NOBOOT:
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return BOOT_DEVICE_RAM;
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}
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return bootmode;
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}
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u32 spl_boot_device(void)
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{
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u32 devstat = readl(CTRLMMR_MAIN_DEVSTAT);
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if (bootindex == K3_PRIMARY_BOOTMODE)
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return __get_primary_bootmedia(devstat);
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else
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return __get_backup_bootmedia(devstat);
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}
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#endif
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#if defined(CONFIG_SYS_K3_SPL_ATF)
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#define AM64X_DEV_RTI8 127
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#define AM64X_DEV_RTI9 128
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#define AM64X_DEV_R5FSS0_CORE0 121
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#define AM64X_DEV_R5FSS0_CORE1 122
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void release_resources_for_core_shutdown(void)
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{
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struct ti_sci_handle *ti_sci = get_ti_sci_handle();
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struct ti_sci_dev_ops *dev_ops = &ti_sci->ops.dev_ops;
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struct ti_sci_proc_ops *proc_ops = &ti_sci->ops.proc_ops;
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int ret;
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u32 i;
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const u32 put_device_ids[] = {
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AM64X_DEV_RTI9,
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AM64X_DEV_RTI8,
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};
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/* Iterate through list of devices to put (shutdown) */
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for (i = 0; i < ARRAY_SIZE(put_device_ids); i++) {
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u32 id = put_device_ids[i];
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ret = dev_ops->put_device(ti_sci, id);
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if (ret)
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panic("Failed to put device %u (%d)\n", id, ret);
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}
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const u32 put_core_ids[] = {
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AM64X_DEV_R5FSS0_CORE1,
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AM64X_DEV_R5FSS0_CORE0, /* Handle CPU0 after CPU1 */
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};
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/* Iterate through list of cores to put (shutdown) */
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for (i = 0; i < ARRAY_SIZE(put_core_ids); i++) {
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u32 id = put_core_ids[i];
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/*
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* Queue up the core shutdown request. Note that this call
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* needs to be followed up by an actual invocation of an WFE
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* or WFI CPU instruction.
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*/
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ret = proc_ops->proc_shutdown_no_wait(ti_sci, id);
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if (ret)
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panic("Failed sending core %u shutdown message (%d)\n",
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id, ret);
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}
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}
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#endif
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