/* * Copyright (c) 2017-2018, ARM Limited and Contributors. All rights reserved. * * SPDX-License-Identifier: BSD-3-Clause */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "../../bl1/bl1_private.h" #include "hikey960_def.h" #include "hikey960_private.h" enum { BOOT_MODE_RECOVERY = 0, BOOT_MODE_NORMAL, BOOT_MODE_MASK = 1, }; /* * Declarations of linker defined symbols which will help us find the layout * of trusted RAM */ /* Data structure which holds the extents of the trusted RAM for BL1 */ static meminfo_t bl1_tzram_layout; /****************************************************************************** * On a GICv2 system, the Group 1 secure interrupts are treated as Group 0 * interrupts. *****************************************************************************/ const unsigned int g0_interrupt_array[] = { IRQ_SEC_PHY_TIMER, IRQ_SEC_SGI_0 }; const gicv2_driver_data_t hikey960_gic_data = { .gicd_base = GICD_REG_BASE, .gicc_base = GICC_REG_BASE, .g0_interrupt_num = ARRAY_SIZE(g0_interrupt_array), .g0_interrupt_array = g0_interrupt_array, }; meminfo_t *bl1_plat_sec_mem_layout(void) { return &bl1_tzram_layout; } /******************************************************************************* * Function that takes a memory layout into which BL2 has been loaded and * populates a new memory layout for BL2 that ensures that BL1's data sections * resident in secure RAM are not visible to BL2. ******************************************************************************/ void bl1_init_bl2_mem_layout(const meminfo_t *bl1_mem_layout, meminfo_t *bl2_mem_layout) { assert(bl1_mem_layout != NULL); assert(bl2_mem_layout != NULL); /* * Cannot remove BL1 RW data from the scope of memory visible to BL2 * like arm platforms because they overlap in hikey960 */ bl2_mem_layout->total_base = BL2_BASE; bl2_mem_layout->total_size = NS_BL1U_LIMIT - BL2_BASE; flush_dcache_range((unsigned long)bl2_mem_layout, sizeof(meminfo_t)); } /* * Perform any BL1 specific platform actions. */ void bl1_early_platform_setup(void) { unsigned int id, uart_base; generic_delay_timer_init(); hikey960_read_boardid(&id); if (id == 5300) uart_base = PL011_UART5_BASE; else uart_base = PL011_UART6_BASE; /* Initialize the console to provide early debug support */ console_init(uart_base, PL011_UART_CLK_IN_HZ, PL011_BAUDRATE); /* Allow BL1 to see the whole Trusted RAM */ bl1_tzram_layout.total_base = BL1_RW_BASE; bl1_tzram_layout.total_size = BL1_RW_SIZE; INFO("BL1: 0x%lx - 0x%lx [size = %lu]\n", BL1_RAM_BASE, BL1_RAM_LIMIT, BL1_RAM_LIMIT - BL1_RAM_BASE); /* bl1_size */ } /* * Perform the very early platform specific architecture setup here. At the * moment this only does basic initialization. Later architectural setup * (bl1_arch_setup()) does not do anything platform specific. */ void bl1_plat_arch_setup(void) { hikey960_init_mmu_el3(bl1_tzram_layout.total_base, bl1_tzram_layout.total_size, BL1_RO_BASE, BL1_RO_LIMIT, BL_COHERENT_RAM_BASE, BL_COHERENT_RAM_END); } static void hikey960_ufs_reset(void) { unsigned int data, mask; mmio_write_32(CRG_PERDIS7_REG, 1 << 14); mmio_clrbits_32(UFS_SYS_PHY_CLK_CTRL_REG, BIT_SYSCTRL_REF_CLOCK_EN); do { data = mmio_read_32(UFS_SYS_PHY_CLK_CTRL_REG); } while (data & BIT_SYSCTRL_REF_CLOCK_EN); /* use abb clk */ mmio_clrbits_32(UFS_SYS_UFS_SYSCTRL_REG, BIT_UFS_REFCLK_SRC_SE1); mmio_clrbits_32(UFS_SYS_PHY_ISO_EN_REG, BIT_UFS_REFCLK_ISO_EN); mmio_write_32(PCTRL_PERI_CTRL3_REG, (1 << 0) | (1 << 16)); mdelay(1); mmio_write_32(CRG_PEREN7_REG, 1 << 14); mmio_setbits_32(UFS_SYS_PHY_CLK_CTRL_REG, BIT_SYSCTRL_REF_CLOCK_EN); mmio_write_32(CRG_PERRSTEN3_REG, PERI_UFS_BIT); do { data = mmio_read_32(CRG_PERRSTSTAT3_REG); } while ((data & PERI_UFS_BIT) == 0); mmio_setbits_32(UFS_SYS_PSW_POWER_CTRL_REG, BIT_UFS_PSW_MTCMOS_EN); mdelay(1); mmio_setbits_32(UFS_SYS_HC_LP_CTRL_REG, BIT_SYSCTRL_PWR_READY); mmio_write_32(UFS_SYS_UFS_DEVICE_RESET_CTRL_REG, MASK_UFS_DEVICE_RESET); /* clear SC_DIV_UFS_PERIBUS */ mask = SC_DIV_UFS_PERIBUS << 16; mmio_write_32(CRG_CLKDIV17_REG, mask); /* set SC_DIV_UFSPHY_CFG(3) */ mask = SC_DIV_UFSPHY_CFG_MASK << 16; data = SC_DIV_UFSPHY_CFG(3); mmio_write_32(CRG_CLKDIV16_REG, mask | data); data = mmio_read_32(UFS_SYS_PHY_CLK_CTRL_REG); data &= ~MASK_SYSCTRL_CFG_CLOCK_FREQ; data |= 0x39; mmio_write_32(UFS_SYS_PHY_CLK_CTRL_REG, data); mmio_clrbits_32(UFS_SYS_PHY_CLK_CTRL_REG, MASK_SYSCTRL_REF_CLOCK_SEL); mmio_setbits_32(UFS_SYS_CLOCK_GATE_BYPASS_REG, MASK_UFS_CLK_GATE_BYPASS); mmio_setbits_32(UFS_SYS_UFS_SYSCTRL_REG, MASK_UFS_SYSCTRL_BYPASS); mmio_setbits_32(UFS_SYS_PSW_CLK_CTRL_REG, BIT_SYSCTRL_PSW_CLK_EN); mmio_clrbits_32(UFS_SYS_PSW_POWER_CTRL_REG, BIT_UFS_PSW_ISO_CTRL); mmio_clrbits_32(UFS_SYS_PHY_ISO_EN_REG, BIT_UFS_PHY_ISO_CTRL); mmio_clrbits_32(UFS_SYS_HC_LP_CTRL_REG, BIT_SYSCTRL_LP_ISOL_EN); mmio_write_32(CRG_PERRSTDIS3_REG, PERI_ARST_UFS_BIT); mmio_setbits_32(UFS_SYS_RESET_CTRL_EN_REG, BIT_SYSCTRL_LP_RESET_N); mdelay(1); mmio_write_32(UFS_SYS_UFS_DEVICE_RESET_CTRL_REG, MASK_UFS_DEVICE_RESET | BIT_UFS_DEVICE_RESET); mdelay(20); mmio_write_32(UFS_SYS_UFS_DEVICE_RESET_CTRL_REG, 0x03300330); mmio_write_32(CRG_PERRSTDIS3_REG, PERI_UFS_BIT); do { data = mmio_read_32(CRG_PERRSTSTAT3_REG); } while (data & PERI_UFS_BIT); } static void hikey960_ufs_init(void) { dw_ufs_params_t ufs_params; memset(&ufs_params, 0, sizeof(ufs_params)); ufs_params.reg_base = UFS_REG_BASE; ufs_params.desc_base = HIKEY960_UFS_DESC_BASE; ufs_params.desc_size = HIKEY960_UFS_DESC_SIZE; if ((ufs_params.flags & UFS_FLAGS_SKIPINIT) == 0) hikey960_ufs_reset(); dw_ufs_init(&ufs_params); } /* * Function which will perform any remaining platform-specific setup that can * occur after the MMU and data cache have been enabled. */ void bl1_platform_setup(void) { hikey960_clk_init(); hikey960_pmu_init(); hikey960_regulator_enable(); hikey960_tzc_init(); hikey960_peri_init(); hikey960_ufs_init(); hikey960_pinmux_init(); hikey960_io_setup(); } /* * The following function checks if Firmware update is needed, * by checking if TOC in FIP image is valid or not. */ unsigned int bl1_plat_get_next_image_id(void) { unsigned int mode, ret; mode = mmio_read_32(SCTRL_BAK_DATA0_REG); switch (mode & BOOT_MODE_MASK) { case BOOT_MODE_RECOVERY: ret = NS_BL1U_IMAGE_ID; break; default: WARN("Invalid boot mode is found:%d\n", mode); panic(); } return ret; } image_desc_t *bl1_plat_get_image_desc(unsigned int image_id) { unsigned int index = 0; while (bl1_tbbr_image_descs[index].image_id != INVALID_IMAGE_ID) { if (bl1_tbbr_image_descs[index].image_id == image_id) return &bl1_tbbr_image_descs[index]; index++; } return NULL; } void bl1_plat_set_ep_info(unsigned int image_id, entry_point_info_t *ep_info) { unsigned int data = 0; uintptr_t tmp = HIKEY960_NS_TMP_OFFSET; if (image_id != NS_BL1U_IMAGE_ID) panic(); /* Copy NS BL1U from 0x1AC1_8000 to 0x1AC9_8000 */ memcpy((void *)tmp, (void *)HIKEY960_NS_IMAGE_OFFSET, NS_BL1U_SIZE); memcpy((void *)NS_BL1U_BASE, (void *)tmp, NS_BL1U_SIZE); inv_dcache_range(NS_BL1U_BASE, NS_BL1U_SIZE); /* Initialize the GIC driver, cpu and distributor interfaces */ gicv2_driver_init(&hikey960_gic_data); gicv2_distif_init(); gicv2_pcpu_distif_init(); gicv2_cpuif_enable(); /* CNTFRQ is read-only in EL1 */ write_cntfrq_el0(plat_get_syscnt_freq2()); data = read_cpacr_el1(); do { data |= 3 << 20; write_cpacr_el1(data); data = read_cpacr_el1(); } while ((data & (3 << 20)) != (3 << 20)); INFO("cpacr_el1:0x%x\n", data); ep_info->args.arg0 = 0xffff & read_mpidr(); ep_info->spsr = SPSR_64(MODE_EL1, MODE_SP_ELX, DISABLE_ALL_EXCEPTIONS); }