/* SPDX-License-Identifier: GPL-2.0-only */ #include #include #include #include #include #include /* This allows USB A-A firmware upload from a compatible host in four parts: * The first two are the bare BL1 and the coreboot boot block, which are just * written to their respective loading addresses. These transfers are initiated * by the IROM / BL1, so this code has nothing to do with them. * * The third transfer is a valid CBFS image that contains only the romstage, * and must be small enough to fit into the PRE_RAM CBFS cache in * IRAM. It is loaded when this function gets called in the boot block, and * the normal CBFS code extracts the romstage from it. * * The fourth transfer is also a CBFS image, but can be of arbitrary size and * should contain all available stages/payloads/etc. It is loaded when this * function is called a second time at the end of the romstage, and copied to * the romstage/ramstage CBFS cache in DRAM. It will reside there for the * rest of the firmware's lifetime and all subsequent stages can just directly * reference it there. */ static int usb_cbfs_open(void) { if (!ENV_ROMSTAGE_OR_BEFORE) return 0; static int first_run = 1; int (*irom_load_usb)(void) = *irom_load_image_from_usb_ptr; if (!first_run) return 0; if (!irom_load_usb()) { printk(BIOS_EMERG, "Unable to load CBFS image via USB!\n"); return -1; } /* * We need to trust the host/irom to copy the image to our * _cbfs_cache address... there is no way to control or even * check the transfer size or target address from our side. */ printk(BIOS_DEBUG, "USB A-A transfer successful, CBFS image should now" " be at %p\n", _cbfs_cache); first_run = 0; return 0; } /* * SDMMC works very similar to USB A-A: we copy the CBFS image into memory * and read it from there. While SDMMC would also allow direct block by block * on-demand reading, we might run into problems if we call back into the IROM * in very late boot stages (e.g. after initializing/changing MMC clocks)... so * this seems like a safer approach. It also makes it easy to pass our image * down to payloads. */ static int sdmmc_cbfs_open(void) { if (!ENV_ROMSTAGE_OR_BEFORE) return 0; /* * In the bootblock, we just copy the small part that fits in the buffer * and hope that it's enough (since the romstage is currently always the * first component in the image, this should work out). In the romstage, * we copy until our cache is full (currently 12M) to avoid the pain of * figuring out the true image size from in here. Since this is mainly a * developer/debug boot mode, those shortcomings should be bearable. */ const u32 count = REGION_SIZE(cbfs_cache) / 512; static int first_run = 1; int (*irom_load_sdmmc)(u32 start, u32 count, void *dst) = *irom_sdmmc_read_blocks_ptr; if (!first_run) return 0; if (!irom_load_sdmmc(1, count, _cbfs_cache)) { printk(BIOS_EMERG, "Unable to load CBFS image from SDMMC!\n"); return -1; } printk(BIOS_DEBUG, "SDMMC read successful, CBFS image should now be" " at %p\n", _cbfs_cache); first_run = 0; return 0; } static struct mem_region_device alternate_rdev = MEM_REGION_DEV_RO_INIT(NULL, 0); const struct region_device *boot_device_ro(void) { if (*iram_secondary_base == SECONDARY_BASE_BOOT_USB) return &alternate_rdev.rdev; switch (exynos_power->om_stat & OM_STAT_MASK) { case OM_STAT_SDMMC: return &alternate_rdev.rdev; case OM_STAT_SPI: return exynos_spi_boot_device(); default: printk(BIOS_EMERG, "Exynos OM_STAT value 0x%x not supported!\n", exynos_power->om_stat); return NULL; } } void boot_device_init(void) { mem_region_device_ro_init(&alternate_rdev, _cbfs_cache, REGION_SIZE(cbfs_cache)); if (*iram_secondary_base == SECONDARY_BASE_BOOT_USB) { printk(BIOS_DEBUG, "Using Exynos alternate boot mode USB A-A\n"); usb_cbfs_open(); return; } switch (exynos_power->om_stat & OM_STAT_MASK) { case OM_STAT_SDMMC: printk(BIOS_DEBUG, "Using Exynos alternate boot mode SDMMC\n"); sdmmc_cbfs_open(); break; case OM_STAT_SPI: exynos_init_spi_boot_device(); break; default: printk(BIOS_EMERG, "Exynos OM_STAT value 0x%x not supported!\n", exynos_power->om_stat); } }