// SPDX-License-Identifier: GPL-2.0+ /* * (C) Copyright 2014 - 2015 Xilinx, Inc. * Michal Simek */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "../common/board.h" #include "pm_cfg_obj.h" #define ZYNQMP_VERSION_SIZE 7 #define EFUSE_VCU_DIS_MASK 0x100 #define EFUSE_VCU_DIS_SHIFT 8 #define EFUSE_GPU_DIS_MASK 0x20 #define EFUSE_GPU_DIS_SHIFT 5 #define IDCODE2_PL_INIT_MASK 0x200 #define IDCODE2_PL_INIT_SHIFT 9 DECLARE_GLOBAL_DATA_PTR; #if CONFIG_IS_ENABLED(FPGA) && defined(CONFIG_FPGA_ZYNQMPPL) static xilinx_desc zynqmppl = XILINX_ZYNQMP_DESC; enum { ZYNQMP_VARIANT_EG = BIT(0U), ZYNQMP_VARIANT_EV = BIT(1U), ZYNQMP_VARIANT_CG = BIT(2U), ZYNQMP_VARIANT_DR = BIT(3U), }; static const struct { u32 id; u8 device; u8 variants; } zynqmp_devices[] = { { .id = 0x04711093, .device = 2, .variants = ZYNQMP_VARIANT_EG | ZYNQMP_VARIANT_CG, }, { .id = 0x04710093, .device = 3, .variants = ZYNQMP_VARIANT_EG | ZYNQMP_VARIANT_CG, }, { .id = 0x04721093, .device = 4, .variants = ZYNQMP_VARIANT_EG | ZYNQMP_VARIANT_CG | ZYNQMP_VARIANT_EV, }, { .id = 0x04720093, .device = 5, .variants = ZYNQMP_VARIANT_EG | ZYNQMP_VARIANT_CG | ZYNQMP_VARIANT_EV, }, { .id = 0x04739093, .device = 6, .variants = ZYNQMP_VARIANT_EG | ZYNQMP_VARIANT_CG, }, { .id = 0x04730093, .device = 7, .variants = ZYNQMP_VARIANT_EG | ZYNQMP_VARIANT_CG | ZYNQMP_VARIANT_EV, }, { .id = 0x04738093, .device = 9, .variants = ZYNQMP_VARIANT_EG | ZYNQMP_VARIANT_CG, }, { .id = 0x04740093, .device = 11, .variants = ZYNQMP_VARIANT_EG, }, { .id = 0x04750093, .device = 15, .variants = ZYNQMP_VARIANT_EG, }, { .id = 0x04759093, .device = 17, .variants = ZYNQMP_VARIANT_EG, }, { .id = 0x04758093, .device = 19, .variants = ZYNQMP_VARIANT_EG, }, { .id = 0x047E1093, .device = 21, .variants = ZYNQMP_VARIANT_DR, }, { .id = 0x047E3093, .device = 23, .variants = ZYNQMP_VARIANT_DR, }, { .id = 0x047E5093, .device = 25, .variants = ZYNQMP_VARIANT_DR, }, { .id = 0x047E4093, .device = 27, .variants = ZYNQMP_VARIANT_DR, }, { .id = 0x047E0093, .device = 28, .variants = ZYNQMP_VARIANT_DR, }, { .id = 0x047E2093, .device = 29, .variants = ZYNQMP_VARIANT_DR, }, { .id = 0x047E6093, .device = 39, .variants = ZYNQMP_VARIANT_DR, }, { .id = 0x047FD093, .device = 43, .variants = ZYNQMP_VARIANT_DR, }, { .id = 0x047F8093, .device = 46, .variants = ZYNQMP_VARIANT_DR, }, { .id = 0x047FF093, .device = 47, .variants = ZYNQMP_VARIANT_DR, }, { .id = 0x047FB093, .device = 48, .variants = ZYNQMP_VARIANT_DR, }, { .id = 0x047FE093, .device = 49, .variants = ZYNQMP_VARIANT_DR, }, { .id = 0x046d0093, .device = 67, .variants = ZYNQMP_VARIANT_DR, }, }; static const struct { u32 id; char *name; } zynqmp_svd_devices[] = { { .id = 0x04714093, .name = "xck24" }, { .id = 0x04724093, .name = "xck26", }, }; static char *zynqmp_detect_svd_name(u32 idcode) { u32 i; for (i = 0; i < ARRAY_SIZE(zynqmp_svd_devices); i++) { if (zynqmp_svd_devices[i].id == (idcode & 0x0FFFFFFF)) return zynqmp_svd_devices[i].name; } return "unknown"; } static char *zynqmp_get_silicon_idcode_name(void) { u32 i; u32 idcode, idcode2; char name[ZYNQMP_VERSION_SIZE]; u32 ret_payload[PAYLOAD_ARG_CNT]; int ret; ret = xilinx_pm_request(PM_GET_CHIPID, 0, 0, 0, 0, ret_payload); if (ret) { debug("%s: Getting chipid failed\n", __func__); return "unknown"; } /* * Firmware returns: * payload[0][31:0] = status of the operation * payload[1]] = IDCODE * payload[2][19:0] = Version * payload[2][28:20] = EXTENDED_IDCODE * payload[2][29] = PL_INIT */ idcode = ret_payload[1]; idcode2 = ret_payload[2] >> ZYNQMP_CSU_VERSION_EMPTY_SHIFT; debug("%s, IDCODE: 0x%0x, IDCODE2: 0x%0x\r\n", __func__, idcode, idcode2); for (i = 0; i < ARRAY_SIZE(zynqmp_devices); i++) { if (zynqmp_devices[i].id == (idcode & 0x0FFFFFFF)) break; } if (i >= ARRAY_SIZE(zynqmp_devices)) return zynqmp_detect_svd_name(idcode); /* Add device prefix to the name */ ret = snprintf(name, ZYNQMP_VERSION_SIZE, "zu%d", zynqmp_devices[i].device); if (ret < 0) return "unknown"; if (zynqmp_devices[i].variants & ZYNQMP_VARIANT_EV) { /* Devices with EV variant might be EG/CG/EV family */ if (idcode2 & IDCODE2_PL_INIT_MASK) { u32 family = ((idcode2 & EFUSE_VCU_DIS_MASK) >> EFUSE_VCU_DIS_SHIFT) << 1 | ((idcode2 & EFUSE_GPU_DIS_MASK) >> EFUSE_GPU_DIS_SHIFT); /* * Get family name based on extended idcode values as * determined on UG1087, EXTENDED_IDCODE register * description */ switch (family) { case 0x00: strncat(name, "ev", 2); break; case 0x10: strncat(name, "eg", 2); break; case 0x11: strncat(name, "cg", 2); break; default: /* Do not append family name*/ break; } } else { /* * When PL powered down the VCU Disable efuse cannot be * read. So, ignore the bit and just findout if it is CG * or EG/EV variant. */ strncat(name, (idcode2 & EFUSE_GPU_DIS_MASK) ? "cg" : "e", 2); } } else if (zynqmp_devices[i].variants & ZYNQMP_VARIANT_CG) { /* Devices with CG variant might be EG or CG family */ strncat(name, (idcode2 & EFUSE_GPU_DIS_MASK) ? "cg" : "eg", 2); } else if (zynqmp_devices[i].variants & ZYNQMP_VARIANT_EG) { strncat(name, "eg", 2); } else if (zynqmp_devices[i].variants & ZYNQMP_VARIANT_DR) { strncat(name, "dr", 2); } else { debug("Variant not identified\n"); } return strdup(name); } #endif int __maybe_unused psu_uboot_init(void) { int ret; ret = psu_init(); if (ret) return ret; /* * PS_SYSMON_ANALOG_BUS register determines mapping between SysMon * supply sense channel to SysMon supply registers inside the IP. * This register must be programmed to complete SysMon IP * configuration. The default register configuration after * power-up is incorrect. Hence, fix this by writing the * correct value - 0x3210. */ writel(ZYNQMP_PS_SYSMON_ANALOG_BUS_VAL, ZYNQMP_AMS_PS_SYSMON_ANALOG_BUS); /* Delay is required for clocks to be propagated */ udelay(1000000); return 0; } #if !defined(CONFIG_SPL_BUILD) # if defined(CONFIG_DEBUG_UART_BOARD_INIT) void board_debug_uart_init(void) { # if defined(CONFIG_ZYNQMP_PSU_INIT_ENABLED) psu_uboot_init(); # endif } # endif # if defined(CONFIG_BOARD_EARLY_INIT_F) int board_early_init_f(void) { int ret = 0; # if defined(CONFIG_ZYNQMP_PSU_INIT_ENABLED) && !defined(CONFIG_DEBUG_UART_BOARD_INIT) ret = psu_uboot_init(); # endif return ret; } # endif #endif static int multi_boot(void) { u32 multiboot = 0; int ret; ret = zynqmp_mmio_read((ulong)&csu_base->multi_boot, &multiboot); if (ret) return -EINVAL; return multiboot; } #if defined(CONFIG_SPL_BUILD) static void restore_jtag(void) { if (current_el() != 3) return; writel(CSU_JTAG_SEC_GATE_DISABLE, &csu_base->jtag_sec); writel(CSU_JTAG_DAP_ENABLE_DEBUG, &csu_base->jtag_dap_cfg); writel(CSU_JTAG_CHAIN_WR_SETUP, &csu_base->jtag_chain_status_wr); writel(CRLAPB_DBG_LPD_CTRL_SETUP_CLK, &crlapb_base->dbg_lpd_ctrl); writel(CRLAPB_RST_LPD_DBG_RESET, &crlapb_base->rst_lpd_dbg); writel(CSU_PCAP_PROG_RELEASE_PL, &csu_base->pcap_prog); } #endif static void print_secure_boot(void) { u32 status = 0; if (zynqmp_mmio_read((ulong)&csu_base->status, &status)) return; printf("Secure Boot:\t%sauthenticated, %sencrypted\n", status & ZYNQMP_CSU_STATUS_AUTHENTICATED ? "" : "not ", status & ZYNQMP_CSU_STATUS_ENCRYPTED ? "" : "not "); } int board_init(void) { #if defined(CONFIG_ZYNQMP_FIRMWARE) struct udevice *dev; uclass_get_device_by_name(UCLASS_FIRMWARE, "zynqmp-power", &dev); if (!dev) panic("PMU Firmware device not found - Enable it"); #endif #if defined(CONFIG_SPL_BUILD) /* Check *at build time* if the filename is an non-empty string */ if (sizeof(CONFIG_ZYNQMP_SPL_PM_CFG_OBJ_FILE) > 1) zynqmp_pmufw_load_config_object(zynqmp_pm_cfg_obj, zynqmp_pm_cfg_obj_size); printf("Silicon version:\t%d\n", zynqmp_get_silicon_version()); /* the CSU disables the JTAG interface when secure boot is enabled */ if (CONFIG_IS_ENABLED(ZYNQMP_RESTORE_JTAG)) restore_jtag(); #else if (CONFIG_IS_ENABLED(DM_I2C) && CONFIG_IS_ENABLED(I2C_EEPROM)) xilinx_read_eeprom(); #endif printf("EL Level:\tEL%d\n", current_el()); #if CONFIG_IS_ENABLED(FPGA) && defined(CONFIG_FPGA_ZYNQMPPL) zynqmppl.name = zynqmp_get_silicon_idcode_name(); printf("Chip ID:\t%s\n", zynqmppl.name); fpga_init(); fpga_add(fpga_xilinx, &zynqmppl); #endif /* display secure boot information */ print_secure_boot(); if (current_el() == 3) printf("Multiboot:\t%d\n", multi_boot()); return 0; } int board_early_init_r(void) { u32 val; if (current_el() != 3) return 0; val = readl(&crlapb_base->timestamp_ref_ctrl); val &= ZYNQMP_CRL_APB_TIMESTAMP_REF_CTRL_CLKACT; if (!val) { val = readl(&crlapb_base->timestamp_ref_ctrl); val |= ZYNQMP_CRL_APB_TIMESTAMP_REF_CTRL_CLKACT; writel(val, &crlapb_base->timestamp_ref_ctrl); /* Program freq register in System counter */ writel(zynqmp_get_system_timer_freq(), &iou_scntr_secure->base_frequency_id_register); /* And enable system counter */ writel(ZYNQMP_IOU_SCNTR_COUNTER_CONTROL_REGISTER_EN, &iou_scntr_secure->counter_control_register); } return 0; } unsigned long do_go_exec(ulong (*entry)(int, char * const []), int argc, char *const argv[]) { int ret = 0; if (current_el() > 1) { smp_kick_all_cpus(); dcache_disable(); armv8_switch_to_el1(0x0, 0, 0, 0, (unsigned long)entry, ES_TO_AARCH64); } else { printf("FAIL: current EL is not above EL1\n"); ret = EINVAL; } return ret; } #if !defined(CONFIG_SYS_SDRAM_BASE) && !defined(CONFIG_SYS_SDRAM_SIZE) int dram_init_banksize(void) { int ret; ret = fdtdec_setup_memory_banksize(); if (ret) return ret; mem_map_fill(); return 0; } int dram_init(void) { if (fdtdec_setup_mem_size_base() != 0) return -EINVAL; return 0; } ulong board_get_usable_ram_top(ulong total_size) { phys_size_t size; phys_addr_t reg; struct lmb lmb; if (!IS_ALIGNED((ulong)gd->fdt_blob, 0x8)) panic("Not 64bit aligned DT location: %p\n", gd->fdt_blob); /* found enough not-reserved memory to relocated U-Boot */ lmb_init(&lmb); lmb_add(&lmb, gd->ram_base, gd->ram_size); boot_fdt_add_mem_rsv_regions(&lmb, (void *)gd->fdt_blob); size = ALIGN(CONFIG_SYS_MALLOC_LEN + total_size, MMU_SECTION_SIZE); reg = lmb_alloc(&lmb, size, MMU_SECTION_SIZE); if (!reg) reg = gd->ram_top - size; return reg + size; } #else int dram_init_banksize(void) { gd->bd->bi_dram[0].start = CONFIG_SYS_SDRAM_BASE; gd->bd->bi_dram[0].size = get_effective_memsize(); mem_map_fill(); return 0; } int dram_init(void) { gd->ram_size = get_ram_size((void *)CONFIG_SYS_SDRAM_BASE, CONFIG_SYS_SDRAM_SIZE); return 0; } #endif #if !CONFIG_IS_ENABLED(SYSRESET) void reset_cpu(void) { } #endif static u8 __maybe_unused zynqmp_get_bootmode(void) { u8 bootmode; u32 reg = 0; int ret; ret = zynqmp_mmio_read((ulong)&crlapb_base->boot_mode, ®); if (ret) return -EINVAL; debug("HW boot mode: %x\n", reg & BOOT_MODES_MASK); debug("ALT boot mode: %x\n", reg >> BOOT_MODE_ALT_SHIFT); if (reg >> BOOT_MODE_ALT_SHIFT) reg >>= BOOT_MODE_ALT_SHIFT; bootmode = reg & BOOT_MODES_MASK; return bootmode; } #if defined(CONFIG_BOARD_LATE_INIT) static const struct { u32 bit; const char *name; } reset_reasons[] = { { RESET_REASON_DEBUG_SYS, "DEBUG" }, { RESET_REASON_SOFT, "SOFT" }, { RESET_REASON_SRST, "SRST" }, { RESET_REASON_PSONLY, "PS-ONLY" }, { RESET_REASON_PMU, "PMU" }, { RESET_REASON_INTERNAL, "INTERNAL" }, { RESET_REASON_EXTERNAL, "EXTERNAL" }, {} }; static int reset_reason(void) { u32 reg; int i, ret; const char *reason = NULL; ret = zynqmp_mmio_read((ulong)&crlapb_base->reset_reason, ®); if (ret) return -EINVAL; puts("Reset reason:\t"); for (i = 0; i < ARRAY_SIZE(reset_reasons); i++) { if (reg & reset_reasons[i].bit) { reason = reset_reasons[i].name; printf("%s ", reset_reasons[i].name); break; } } puts("\n"); env_set("reset_reason", reason); return 0; } static int set_fdtfile(void) { char *compatible, *fdtfile; const char *suffix = ".dtb"; const char *vendor = "xilinx/"; int fdt_compat_len; if (env_get("fdtfile")) return 0; compatible = (char *)fdt_getprop(gd->fdt_blob, 0, "compatible", &fdt_compat_len); if (compatible && fdt_compat_len) { char *name; debug("Compatible: %s\n", compatible); name = strchr(compatible, ','); if (!name) return -EINVAL; name++; fdtfile = calloc(1, strlen(vendor) + strlen(name) + strlen(suffix) + 1); if (!fdtfile) return -ENOMEM; sprintf(fdtfile, "%s%s%s", vendor, name, suffix); env_set("fdtfile", fdtfile); free(fdtfile); } return 0; } int board_late_init(void) { u8 bootmode; struct udevice *dev; int bootseq = -1; int bootseq_len = 0; int env_targets_len = 0; const char *mode; char *new_targets; char *env_targets; int ret, multiboot; #if defined(CONFIG_USB_ETHER) && !defined(CONFIG_USB_GADGET_DOWNLOAD) usb_ether_init(); #endif if (!(gd->flags & GD_FLG_ENV_DEFAULT)) { debug("Saved variables - Skipping\n"); return 0; } if (!CONFIG_IS_ENABLED(ENV_VARS_UBOOT_RUNTIME_CONFIG)) return 0; ret = set_fdtfile(); if (ret) return ret; multiboot = multi_boot(); if (multiboot >= 0) env_set_hex("multiboot", multiboot); bootmode = zynqmp_get_bootmode(); puts("Bootmode: "); switch (bootmode) { case USB_MODE: puts("USB_MODE\n"); mode = "usb_dfu0 usb_dfu1"; env_set("modeboot", "usb_dfu_spl"); break; case JTAG_MODE: puts("JTAG_MODE\n"); mode = "jtag pxe dhcp"; env_set("modeboot", "jtagboot"); break; case QSPI_MODE_24BIT: case QSPI_MODE_32BIT: mode = "qspi0"; puts("QSPI_MODE\n"); env_set("modeboot", "qspiboot"); break; case EMMC_MODE: puts("EMMC_MODE\n"); if (uclass_get_device_by_name(UCLASS_MMC, "mmc@ff160000", &dev) && uclass_get_device_by_name(UCLASS_MMC, "sdhci@ff160000", &dev)) { puts("Boot from EMMC but without SD0 enabled!\n"); return -1; } debug("mmc0 device found at %p, seq %d\n", dev, dev_seq(dev)); mode = "mmc"; bootseq = dev_seq(dev); env_set("modeboot", "emmcboot"); break; case SD_MODE: puts("SD_MODE\n"); if (uclass_get_device_by_name(UCLASS_MMC, "mmc@ff160000", &dev) && uclass_get_device_by_name(UCLASS_MMC, "sdhci@ff160000", &dev)) { puts("Boot from SD0 but without SD0 enabled!\n"); return -1; } debug("mmc0 device found at %p, seq %d\n", dev, dev_seq(dev)); mode = "mmc"; bootseq = dev_seq(dev); env_set("modeboot", "sdboot"); break; case SD1_LSHFT_MODE: puts("LVL_SHFT_"); fallthrough; case SD_MODE1: puts("SD_MODE1\n"); if (uclass_get_device_by_name(UCLASS_MMC, "mmc@ff170000", &dev) && uclass_get_device_by_name(UCLASS_MMC, "sdhci@ff170000", &dev)) { puts("Boot from SD1 but without SD1 enabled!\n"); return -1; } debug("mmc1 device found at %p, seq %d\n", dev, dev_seq(dev)); mode = "mmc"; bootseq = dev_seq(dev); env_set("modeboot", "sdboot"); break; case NAND_MODE: puts("NAND_MODE\n"); mode = "nand0"; env_set("modeboot", "nandboot"); break; default: mode = ""; printf("Invalid Boot Mode:0x%x\n", bootmode); break; } if (bootseq >= 0) { bootseq_len = snprintf(NULL, 0, "%i", bootseq); debug("Bootseq len: %x\n", bootseq_len); env_set_hex("bootseq", bootseq); } /* * One terminating char + one byte for space between mode * and default boot_targets */ env_targets = env_get("boot_targets"); if (env_targets) env_targets_len = strlen(env_targets); new_targets = calloc(1, strlen(mode) + env_targets_len + 2 + bootseq_len); if (!new_targets) return -ENOMEM; if (bootseq >= 0) sprintf(new_targets, "%s%x %s", mode, bootseq, env_targets ? env_targets : ""); else sprintf(new_targets, "%s %s", mode, env_targets ? env_targets : ""); env_set("boot_targets", new_targets); free(new_targets); reset_reason(); return board_late_init_xilinx(); } #endif int checkboard(void) { puts("Board: Xilinx ZynqMP\n"); return 0; } int mmc_get_env_dev(void) { struct udevice *dev; int bootseq = 0; switch (zynqmp_get_bootmode()) { case EMMC_MODE: case SD_MODE: if (uclass_get_device_by_name(UCLASS_MMC, "mmc@ff160000", &dev) && uclass_get_device_by_name(UCLASS_MMC, "sdhci@ff160000", &dev)) { return -1; } bootseq = dev_seq(dev); break; case SD1_LSHFT_MODE: case SD_MODE1: if (uclass_get_device_by_name(UCLASS_MMC, "mmc@ff170000", &dev) && uclass_get_device_by_name(UCLASS_MMC, "sdhci@ff170000", &dev)) { return -1; } bootseq = dev_seq(dev); break; default: break; } debug("bootseq %d\n", bootseq); return bootseq; } enum env_location env_get_location(enum env_operation op, int prio) { u32 bootmode = zynqmp_get_bootmode(); if (prio) return ENVL_UNKNOWN; switch (bootmode) { case EMMC_MODE: case SD_MODE: case SD1_LSHFT_MODE: case SD_MODE1: if (IS_ENABLED(CONFIG_ENV_IS_IN_FAT)) return ENVL_FAT; if (IS_ENABLED(CONFIG_ENV_IS_IN_EXT4)) return ENVL_EXT4; return ENVL_NOWHERE; case NAND_MODE: if (IS_ENABLED(CONFIG_ENV_IS_IN_NAND)) return ENVL_NAND; if (IS_ENABLED(CONFIG_ENV_IS_IN_UBI)) return ENVL_UBI; return ENVL_NOWHERE; case QSPI_MODE_24BIT: case QSPI_MODE_32BIT: if (IS_ENABLED(CONFIG_ENV_IS_IN_SPI_FLASH)) return ENVL_SPI_FLASH; return ENVL_NOWHERE; case JTAG_MODE: default: return ENVL_NOWHERE; } } #if defined(CONFIG_SET_DFU_ALT_INFO) #define DFU_ALT_BUF_LEN SZ_1K void set_dfu_alt_info(char *interface, char *devstr) { u8 multiboot; int bootseq = 0; ALLOC_CACHE_ALIGN_BUFFER(char, buf, DFU_ALT_BUF_LEN); if (env_get("dfu_alt_info")) return; memset(buf, 0, sizeof(buf)); multiboot = multi_boot(); if (multiboot < 0) multiboot = 0; multiboot = env_get_hex("multiboot", multiboot); debug("Multiboot: %d\n", multiboot); switch (zynqmp_get_bootmode()) { case EMMC_MODE: case SD_MODE: case SD1_LSHFT_MODE: case SD_MODE1: bootseq = mmc_get_env_dev(); if (!multiboot) snprintf(buf, DFU_ALT_BUF_LEN, "mmc %d:1=boot.bin fat %d 1;" "%s fat %d 1", bootseq, bootseq, CONFIG_SPL_FS_LOAD_PAYLOAD_NAME, bootseq); else snprintf(buf, DFU_ALT_BUF_LEN, "mmc %d:1=boot%04d.bin fat %d 1;" "%s fat %d 1", bootseq, multiboot, bootseq, CONFIG_SPL_FS_LOAD_PAYLOAD_NAME, bootseq); break; case QSPI_MODE_24BIT: case QSPI_MODE_32BIT: snprintf(buf, DFU_ALT_BUF_LEN, "sf 0:0=boot.bin raw %x 0x1500000;" "%s raw 0x%x 0x500000", multiboot * SZ_32K, CONFIG_SPL_FS_LOAD_PAYLOAD_NAME, CONFIG_SYS_SPI_U_BOOT_OFFS); break; default: return; } env_set("dfu_alt_info", buf); puts("DFU alt info setting: done\n"); } #endif