/* * Copyright (c) 2018, ARM Limited and Contributors. All rights reserved. * * SPDX-License-Identifier: BSD-3-Clause */ #include #include #include #include #include #include #include #include #include "n1sdp_def.h" /* * Memory information structure stored in SDS. * This structure holds the total DDR memory size which will be * used when zeroing out the entire DDR memory before enabling * the ECC capability in DMCs. */ struct n1sdp_mem_info { uint32_t ddr_size_gb; }; /* * BL33 image information structure stored in SDS. * This structure holds the source & destination addresses and * the size of the BL33 image which will be loaded by BL31. */ struct n1sdp_bl33_info { uint32_t bl33_src_addr; uint32_t bl33_dst_addr; uint32_t bl33_size; }; static scmi_channel_plat_info_t n1sdp_scmi_plat_info = { .scmi_mbx_mem = N1SDP_SCMI_PAYLOAD_BASE, .db_reg_addr = PLAT_CSS_MHU_BASE + CSS_SCMI_MHU_DB_REG_OFF, .db_preserve_mask = 0xfffffffe, .db_modify_mask = 0x1, .ring_doorbell = &mhu_ring_doorbell, }; scmi_channel_plat_info_t *plat_css_get_scmi_info() { return &n1sdp_scmi_plat_info; } const plat_psci_ops_t *plat_arm_psci_override_pm_ops(plat_psci_ops_t *ops) { return css_scmi_override_pm_ops(ops); } /* * N1SDP platform supports RDIMMs with ECC capability. To use the ECC * capability, the entire DDR memory space has to be zeroed out before * enabling the ECC bits in DMC620. Zeroing out several gigabytes of * memory from SCP is quite time consuming so the following function * is added to zero out the DDR memory from application processor which is * much faster compared to SCP. BL33 binary cannot be copied to DDR memory * before enabling ECC so copy_bl33 function is added to copy BL33 binary * from IOFPGA-DDR3 memory to main DDR4 memory. */ void dmc_ecc_setup(uint32_t ddr_size_gb) { uint64_t dram2_size; dram2_size = (ddr_size_gb * 1024UL * 1024UL * 1024UL) - ARM_DRAM1_SIZE; INFO("Zeroing DDR memories\n"); zero_normalmem((void *)ARM_DRAM1_BASE, ARM_DRAM1_SIZE); flush_dcache_range(ARM_DRAM1_BASE, ARM_DRAM1_SIZE); zero_normalmem((void *)ARM_DRAM2_BASE, dram2_size); flush_dcache_range(ARM_DRAM2_BASE, dram2_size); INFO("Enabling ECC on DMCs\n"); mmio_setbits_32(N1SDP_DMC0_ERR0CTLR0_REG, N1SDP_DMC_ERR0CTLR0_ECC_EN); mmio_setbits_32(N1SDP_DMC1_ERR0CTLR0_REG, N1SDP_DMC_ERR0CTLR0_ECC_EN); } void copy_bl33(uint32_t src, uint32_t dst, uint32_t size) { uint32_t i; INFO("Copying BL33 to DDR memory\n"); for (i = 0; i < size; i = i + 8) mmio_write_64((dst + i), mmio_read_64(src + i)); for (i = 0; i < size; i = i + 8) { if (mmio_read_64(src + i) != mmio_read_64(dst + i)) { ERROR("Copy failed!\n"); panic(); } } } void bl31_platform_setup(void) { int ret; struct n1sdp_mem_info mem_info; struct n1sdp_bl33_info bl33_info; arm_bl31_platform_setup(); ret = sds_init(); if (ret != SDS_OK) { ERROR("SDS initialization failed\n"); panic(); } ret = sds_struct_read(N1SDP_SDS_MEM_INFO_STRUCT_ID, N1SDP_SDS_MEM_INFO_OFFSET, &mem_info, N1SDP_SDS_MEM_INFO_SIZE, SDS_ACCESS_MODE_NON_CACHED); if (ret != SDS_OK) { ERROR("Error getting memory info from SDS\n"); panic(); } dmc_ecc_setup(mem_info.ddr_size_gb); ret = sds_struct_read(N1SDP_SDS_BL33_INFO_STRUCT_ID, N1SDP_SDS_BL33_INFO_OFFSET, &bl33_info, N1SDP_SDS_BL33_INFO_SIZE, SDS_ACCESS_MODE_NON_CACHED); if (ret != SDS_OK) { ERROR("Error getting BL33 info from SDS\n"); panic(); } copy_bl33(bl33_info.bl33_src_addr, bl33_info.bl33_dst_addr, bl33_info.bl33_size); /* * Pass DDR memory size info to BL33. This method is followed as * currently there is no BL1/BL2 involved in boot flow of N1SDP. * When TBBR is implemented for N1SDP, this method should be removed * and DDR memory size shoule be passed to BL33 using NT_FW_CONFIG * passing mechanism. */ mmio_write_32(N1SDP_DDR_MEM_INFO_BASE, mem_info.ddr_size_gb); }