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git01.mediatek.com / filogic / atf / 8eb61b71403f47f82979fdb6300023e6878f2d3f / . / plat / arm / board / fvp / fvp_common.c
blob: 283918bb03e60bd1da8f4533d4d8cc68a9d87b4d [file] [log] [blame]
/*
* Copyright (c) 2013-2023, Arm Limited and Contributors. All rights reserved.
*
* SPDX-License-Identifier: BSD-3-Clause
*/
#include <assert.h>
#include <common/debug.h>
#include <drivers/arm/cci.h>
#include <drivers/arm/ccn.h>
#include <drivers/arm/gicv2.h>
#include <drivers/arm/sp804_delay_timer.h>
#include <drivers/generic_delay_timer.h>
#include <fconf_hw_config_getter.h>
#include <lib/mmio.h>
#include <lib/smccc.h>
#include <lib/xlat_tables/xlat_tables_compat.h>
#include <platform_def.h>
#include <services/arm_arch_svc.h>
#include <services/rmm_core_manifest.h>
#if SPM_MM
#include <services/spm_mm_partition.h>
#endif
#include <plat/arm/common/arm_config.h>
#include <plat/arm/common/arm_pas_def.h>
#include <plat/arm/common/plat_arm.h>
#include <plat/common/platform.h>
#include "fvp_private.h"
/* Defines for GIC Driver build time selection */
#define FVP_GICV2 1
#define FVP_GICV3 2
/*******************************************************************************
* arm_config holds the characteristics of the differences between the three FVP
* platforms (Base, A53_A57 & Foundation). It will be populated during cold boot
* at each boot stage by the primary before enabling the MMU (to allow
* interconnect configuration) & used thereafter. Each BL will have its own copy
* to allow independent operation.
******************************************************************************/
arm_config_t arm_config;
#define MAP_DEVICE0 MAP_REGION_FLAT(DEVICE0_BASE, \
DEVICE0_SIZE, \
MT_DEVICE | MT_RW | MT_SECURE)
#define MAP_DEVICE1 MAP_REGION_FLAT(DEVICE1_BASE, \
DEVICE1_SIZE, \
MT_DEVICE | MT_RW | MT_SECURE)
#if FVP_GICR_REGION_PROTECTION
#define MAP_GICD_MEM MAP_REGION_FLAT(BASE_GICD_BASE, \
BASE_GICD_SIZE, \
MT_DEVICE | MT_RW | MT_SECURE)
/* Map all core's redistributor memory as read-only. After boots up,
* per-core map its redistributor memory as read-write */
#define MAP_GICR_MEM MAP_REGION_FLAT(BASE_GICR_BASE, \
(BASE_GICR_SIZE * PLATFORM_CORE_COUNT),\
MT_DEVICE | MT_RO | MT_SECURE)
#endif /* FVP_GICR_REGION_PROTECTION */
/*
* Need to be mapped with write permissions in order to set a new non-volatile
* counter value.
*/
#define MAP_DEVICE2 MAP_REGION_FLAT(DEVICE2_BASE, \
DEVICE2_SIZE, \
MT_DEVICE | MT_RW | MT_SECURE)
/*
* Table of memory regions for various BL stages to map using the MMU.
* This doesn't include Trusted SRAM as setup_page_tables() already takes care
* of mapping it.
*/
#ifdef IMAGE_BL1
const mmap_region_t plat_arm_mmap[] = {
ARM_MAP_SHARED_RAM,
V2M_MAP_FLASH0_RO,
V2M_MAP_IOFPGA,
MAP_DEVICE0,
#if FVP_INTERCONNECT_DRIVER == FVP_CCN
MAP_DEVICE1,
#endif
#if TRUSTED_BOARD_BOOT
/* To access the Root of Trust Public Key registers. */
MAP_DEVICE2,
/* Map DRAM to authenticate NS_BL2U image. */
ARM_MAP_NS_DRAM1,
#endif
{0}
};
#endif
#ifdef IMAGE_BL2
const mmap_region_t plat_arm_mmap[] = {
ARM_MAP_SHARED_RAM,
V2M_MAP_FLASH0_RW,
V2M_MAP_IOFPGA,
MAP_DEVICE0,
#if FVP_INTERCONNECT_DRIVER == FVP_CCN
MAP_DEVICE1,
#endif
ARM_MAP_NS_DRAM1,
#ifdef __aarch64__
ARM_MAP_DRAM2,
#endif
/*
* Required to load HW_CONFIG, SPMC and SPs to trusted DRAM.
*/
ARM_MAP_TRUSTED_DRAM,
/*
* Required to load Event Log in TZC secured memory
*/
#if MEASURED_BOOT && (defined(SPD_tspd) || defined(SPD_opteed) || \
defined(SPD_spmd))
ARM_MAP_EVENT_LOG_DRAM1,
#endif /* MEASURED_BOOT && (SPD_tspd || SPD_opteed || SPD_spmd) */
#if ENABLE_RME
ARM_MAP_RMM_DRAM,
ARM_MAP_GPT_L1_DRAM,
#endif /* ENABLE_RME */
#ifdef SPD_tspd
ARM_MAP_TSP_SEC_MEM,
#endif
#if TRUSTED_BOARD_BOOT
/* To access the Root of Trust Public Key registers. */
MAP_DEVICE2,
#endif /* TRUSTED_BOARD_BOOT */
#if CRYPTO_SUPPORT && !RESET_TO_BL2
/*
* To access shared the Mbed TLS heap while booting the
* system with Crypto support
*/
ARM_MAP_BL1_RW,
#endif /* CRYPTO_SUPPORT && !RESET_TO_BL2 */
#if SPM_MM || SPMC_AT_EL3
ARM_SP_IMAGE_MMAP,
#endif
#if ARM_BL31_IN_DRAM
ARM_MAP_BL31_SEC_DRAM,
#endif
#ifdef SPD_opteed
ARM_MAP_OPTEE_CORE_MEM,
ARM_OPTEE_PAGEABLE_LOAD_MEM,
#endif
{0}
};
#endif
#ifdef IMAGE_BL2U
const mmap_region_t plat_arm_mmap[] = {
MAP_DEVICE0,
V2M_MAP_IOFPGA,
{0}
};
#endif
#ifdef IMAGE_BL31
const mmap_region_t plat_arm_mmap[] = {
ARM_MAP_SHARED_RAM,
#if USE_DEBUGFS
/* Required by devfip, can be removed if devfip is not used */
V2M_MAP_FLASH0_RW,
#endif /* USE_DEBUGFS */
ARM_MAP_EL3_TZC_DRAM,
V2M_MAP_IOFPGA,
MAP_DEVICE0,
#if FVP_GICR_REGION_PROTECTION
MAP_GICD_MEM,
MAP_GICR_MEM,
#else
MAP_DEVICE1,
#endif /* FVP_GICR_REGION_PROTECTION */
ARM_V2M_MAP_MEM_PROTECT,
#if SPM_MM
ARM_SPM_BUF_EL3_MMAP,
#endif
#if ENABLE_RME
ARM_MAP_GPT_L1_DRAM,
ARM_MAP_EL3_RMM_SHARED_MEM,
#endif
{0}
};
#if defined(IMAGE_BL31) && SPM_MM
const mmap_region_t plat_arm_secure_partition_mmap[] = {
V2M_MAP_IOFPGA_EL0, /* for the UART */
MAP_REGION_FLAT(DEVICE0_BASE,
DEVICE0_SIZE,
MT_DEVICE | MT_RO | MT_SECURE | MT_USER),
ARM_SP_IMAGE_MMAP,
ARM_SP_IMAGE_NS_BUF_MMAP,
ARM_SP_IMAGE_RW_MMAP,
ARM_SPM_BUF_EL0_MMAP,
{0}
};
#endif
#endif
#ifdef IMAGE_BL32
const mmap_region_t plat_arm_mmap[] = {
#ifndef __aarch64__
ARM_MAP_SHARED_RAM,
ARM_V2M_MAP_MEM_PROTECT,
#endif
V2M_MAP_IOFPGA,
MAP_DEVICE0,
MAP_DEVICE1,
{0}
};
#endif
#ifdef IMAGE_RMM
const mmap_region_t plat_arm_mmap[] = {
V2M_MAP_IOFPGA,
MAP_DEVICE0,
MAP_DEVICE1,
{0}
};
#endif
ARM_CASSERT_MMAP
#if FVP_INTERCONNECT_DRIVER != FVP_CCN
static const int fvp_cci400_map[] = {
PLAT_FVP_CCI400_CLUS0_SL_PORT,
PLAT_FVP_CCI400_CLUS1_SL_PORT,
};
static const int fvp_cci5xx_map[] = {
PLAT_FVP_CCI5XX_CLUS0_SL_PORT,
PLAT_FVP_CCI5XX_CLUS1_SL_PORT,
};
static unsigned int get_interconnect_master(void)
{
unsigned int master;
u_register_t mpidr;
mpidr = read_mpidr_el1();
master = ((arm_config.flags & ARM_CONFIG_FVP_SHIFTED_AFF) != 0U) ?
MPIDR_AFFLVL2_VAL(mpidr) : MPIDR_AFFLVL1_VAL(mpidr);
assert(master < FVP_CLUSTER_COUNT);
return master;
}
#endif
#if defined(IMAGE_BL31) && SPM_MM
/*
* Boot information passed to a secure partition during initialisation. Linear
* indices in MP information will be filled at runtime.
*/
static spm_mm_mp_info_t sp_mp_info[] = {
[0] = {0x80000000, 0},
[1] = {0x80000001, 0},
[2] = {0x80000002, 0},
[3] = {0x80000003, 0},
[4] = {0x80000100, 0},
[5] = {0x80000101, 0},
[6] = {0x80000102, 0},
[7] = {0x80000103, 0},
};
const spm_mm_boot_info_t plat_arm_secure_partition_boot_info = {
.h.type = PARAM_SP_IMAGE_BOOT_INFO,
.h.version = VERSION_1,
.h.size = sizeof(spm_mm_boot_info_t),
.h.attr = 0,
.sp_mem_base = ARM_SP_IMAGE_BASE,
.sp_mem_limit = ARM_SP_IMAGE_LIMIT,
.sp_image_base = ARM_SP_IMAGE_BASE,
.sp_stack_base = PLAT_SP_IMAGE_STACK_BASE,
.sp_heap_base = ARM_SP_IMAGE_HEAP_BASE,
.sp_ns_comm_buf_base = PLAT_SP_IMAGE_NS_BUF_BASE,
.sp_shared_buf_base = PLAT_SPM_BUF_BASE,
.sp_image_size = ARM_SP_IMAGE_SIZE,
.sp_pcpu_stack_size = PLAT_SP_IMAGE_STACK_PCPU_SIZE,
.sp_heap_size = ARM_SP_IMAGE_HEAP_SIZE,
.sp_ns_comm_buf_size = PLAT_SP_IMAGE_NS_BUF_SIZE,
.sp_shared_buf_size = PLAT_SPM_BUF_SIZE,
.num_sp_mem_regions = ARM_SP_IMAGE_NUM_MEM_REGIONS,
.num_cpus = PLATFORM_CORE_COUNT,
.mp_info = &sp_mp_info[0],
};
const struct mmap_region *plat_get_secure_partition_mmap(void *cookie)
{
return plat_arm_secure_partition_mmap;
}
const struct spm_mm_boot_info *plat_get_secure_partition_boot_info(
void *cookie)
{
return &plat_arm_secure_partition_boot_info;
}
#endif
/*******************************************************************************
* A single boot loader stack is expected to work on both the Foundation FVP
* models and the two flavours of the Base FVP models (AEMv8 & Cortex). The
* SYS_ID register provides a mechanism for detecting the differences between
* these platforms. This information is stored in a per-BL array to allow the
* code to take the correct path.Per BL platform configuration.
******************************************************************************/
void __init fvp_config_setup(void)
{
unsigned int rev, hbi, bld, arch, sys_id;
sys_id = mmio_read_32(V2M_SYSREGS_BASE + V2M_SYS_ID);
rev = (sys_id >> V2M_SYS_ID_REV_SHIFT) & V2M_SYS_ID_REV_MASK;
hbi = (sys_id >> V2M_SYS_ID_HBI_SHIFT) & V2M_SYS_ID_HBI_MASK;
bld = (sys_id >> V2M_SYS_ID_BLD_SHIFT) & V2M_SYS_ID_BLD_MASK;
arch = (sys_id >> V2M_SYS_ID_ARCH_SHIFT) & V2M_SYS_ID_ARCH_MASK;
if (arch != ARCH_MODEL) {
ERROR("This firmware is for FVP models\n");
panic();
}
/*
* The build field in the SYS_ID tells which variant of the GIC
* memory is implemented by the model.
*/
switch (bld) {
case BLD_GIC_VE_MMAP:
ERROR("Legacy Versatile Express memory map for GIC peripheral"
" is not supported\n");
panic();
break;
case BLD_GIC_A53A57_MMAP:
break;
default:
ERROR("Unsupported board build %x\n", bld);
panic();
}
/*
* The hbi field in the SYS_ID is 0x020 for the Base FVP & 0x010
* for the Foundation FVP.
*/
switch (hbi) {
case HBI_FOUNDATION_FVP:
arm_config.flags = 0;
/*
* Check for supported revisions of Foundation FVP
* Allow future revisions to run but emit warning diagnostic
*/
switch (rev) {
case REV_FOUNDATION_FVP_V2_0:
case REV_FOUNDATION_FVP_V2_1:
case REV_FOUNDATION_FVP_v9_1:
case REV_FOUNDATION_FVP_v9_6:
break;
default:
WARN("Unrecognized Foundation FVP revision %x\n", rev);
break;
}
break;
case HBI_BASE_FVP:
arm_config.flags |= (ARM_CONFIG_BASE_MMAP | ARM_CONFIG_HAS_TZC);
/*
* Check for supported revisions
* Allow future revisions to run but emit warning diagnostic
*/
switch (rev) {
case REV_BASE_FVP_V0:
arm_config.flags |= ARM_CONFIG_FVP_HAS_CCI400;
break;
case REV_BASE_FVP_REVC:
arm_config.flags |= (ARM_CONFIG_FVP_HAS_SMMUV3 |
ARM_CONFIG_FVP_HAS_CCI5XX);
break;
default:
WARN("Unrecognized Base FVP revision %x\n", rev);
break;
}
break;
default:
ERROR("Unsupported board HBI number 0x%x\n", hbi);
panic();
}
/*
* We assume that the presence of MT bit, and therefore shifted
* affinities, is uniform across the platform: either all CPUs, or no
* CPUs implement it.
*/
if ((read_mpidr_el1() & MPIDR_MT_MASK) != 0U)
arm_config.flags |= ARM_CONFIG_FVP_SHIFTED_AFF;
}
void __init fvp_interconnect_init(void)
{
#if FVP_INTERCONNECT_DRIVER == FVP_CCN
if (ccn_get_part0_id(PLAT_ARM_CCN_BASE) != CCN_502_PART0_ID) {
ERROR("Unrecognized CCN variant detected. Only CCN-502 is supported");
panic();
}
plat_arm_interconnect_init();
#else
uintptr_t cci_base = 0U;
const int *cci_map = NULL;
unsigned int map_size = 0U;
/* Initialize the right interconnect */
if ((arm_config.flags & ARM_CONFIG_FVP_HAS_CCI5XX) != 0U) {
cci_base = PLAT_FVP_CCI5XX_BASE;
cci_map = fvp_cci5xx_map;
map_size = ARRAY_SIZE(fvp_cci5xx_map);
} else if ((arm_config.flags & ARM_CONFIG_FVP_HAS_CCI400) != 0U) {
cci_base = PLAT_FVP_CCI400_BASE;
cci_map = fvp_cci400_map;
map_size = ARRAY_SIZE(fvp_cci400_map);
} else {
return;
}
assert(cci_base != 0U);
assert(cci_map != NULL);
cci_init(cci_base, cci_map, map_size);
#endif
}
void fvp_interconnect_enable(void)
{
#if FVP_INTERCONNECT_DRIVER == FVP_CCN
plat_arm_interconnect_enter_coherency();
#else
unsigned int master;
if ((arm_config.flags & (ARM_CONFIG_FVP_HAS_CCI400 |
ARM_CONFIG_FVP_HAS_CCI5XX)) != 0U) {
master = get_interconnect_master();
cci_enable_snoop_dvm_reqs(master);
}
#endif
}
void fvp_interconnect_disable(void)
{
#if FVP_INTERCONNECT_DRIVER == FVP_CCN
plat_arm_interconnect_exit_coherency();
#else
unsigned int master;
if ((arm_config.flags & (ARM_CONFIG_FVP_HAS_CCI400 |
ARM_CONFIG_FVP_HAS_CCI5XX)) != 0U) {
master = get_interconnect_master();
cci_disable_snoop_dvm_reqs(master);
}
#endif
}
#if CRYPTO_SUPPORT
int plat_get_mbedtls_heap(void **heap_addr, size_t *heap_size)
{
assert(heap_addr != NULL);
assert(heap_size != NULL);
return arm_get_mbedtls_heap(heap_addr, heap_size);
}
#endif /* CRYPTO_SUPPORT */
void fvp_timer_init(void)
{
#if USE_SP804_TIMER
/* Enable the clock override for SP804 timer 0, which means that no
* clock dividers are applied and the raw (35MHz) clock will be used.
*/
mmio_write_32(V2M_SP810_BASE, FVP_SP810_CTRL_TIM0_OV);
/* Initialize delay timer driver using SP804 dual timer 0 */
sp804_timer_init(V2M_SP804_TIMER0_BASE,
SP804_TIMER_CLKMULT, SP804_TIMER_CLKDIV);
#else
generic_delay_timer_init();
/* Enable System level generic timer */
mmio_write_32(ARM_SYS_CNTCTL_BASE + CNTCR_OFF,
CNTCR_FCREQ(0U) | CNTCR_EN);
#endif /* USE_SP804_TIMER */
}
/*****************************************************************************
* plat_is_smccc_feature_available() - This function checks whether SMCCC
* feature is availabile for platform.
* @fid: SMCCC function id
*
* Return SMC_ARCH_CALL_SUCCESS if SMCCC feature is available and
* SMC_ARCH_CALL_NOT_SUPPORTED otherwise.
*****************************************************************************/
int32_t plat_is_smccc_feature_available(u_register_t fid)
{
switch (fid) {
case SMCCC_ARCH_SOC_ID:
return SMC_ARCH_CALL_SUCCESS;
default:
return SMC_ARCH_CALL_NOT_SUPPORTED;
}
}
/* Get SOC version */
int32_t plat_get_soc_version(void)
{
return (int32_t)
(SOC_ID_SET_JEP_106(ARM_SOC_CONTINUATION_CODE,
ARM_SOC_IDENTIFICATION_CODE) |
(FVP_SOC_ID & SOC_ID_IMPL_DEF_MASK));
}
/* Get SOC revision */
int32_t plat_get_soc_revision(void)
{
unsigned int sys_id;
sys_id = mmio_read_32(V2M_SYSREGS_BASE + V2M_SYS_ID);
return (int32_t)(((sys_id >> V2M_SYS_ID_REV_SHIFT) &
V2M_SYS_ID_REV_MASK) & SOC_ID_REV_MASK);
}
#if ENABLE_RME
/*
* Get a pointer to the RMM-EL3 Shared buffer and return it
* through the pointer passed as parameter.
*
* This function returns the size of the shared buffer.
*/
size_t plat_rmmd_get_el3_rmm_shared_mem(uintptr_t *shared)
{
*shared = (uintptr_t)RMM_SHARED_BASE;
return (size_t)RMM_SHARED_SIZE;
}
int plat_rmmd_load_manifest(struct rmm_manifest *manifest)
{
uint64_t checksum, num_banks;
struct ns_dram_bank *bank_ptr;
assert(manifest != NULL);
/* Get number of DRAM banks */
num_banks = FCONF_GET_PROPERTY(hw_config, dram_layout, num_banks);
assert(num_banks <= ARM_DRAM_NUM_BANKS);
manifest->version = RMMD_MANIFEST_VERSION;
manifest->padding = 0U; /* RES0 */
manifest->plat_data = (uintptr_t)NULL;
manifest->plat_dram.num_banks = num_banks;
/*
* Array ns_dram_banks[] follows ns_dram_info structure:
*
* +-----------------------------------+
* | offset | field | comment |
* +----------+-----------+------------+
* | 0 | version | 0x00000002 |
* +----------+-----------+------------+
* | 4 | padding | 0x00000000 |
* +----------+-----------+------------+
* | 8 | plat_data | NULL |
* +----------+-----------+------------+
* | 16 | num_banks | |
* +----------+-----------+ |
* | 24 | banks | plat_dram |
* +----------+-----------+ |
* | 32 | checksum | |
* +----------+-----------+------------+
* | 40 | base 0 | |
* +----------+-----------+ bank[0] |
* | 48 | size 0 | |
* +----------+-----------+------------+
* | 56 | base 1 | |
* +----------+-----------+ bank[1] |
* | 64 | size 1 | |
* +----------+-----------+------------+
*/
bank_ptr = (struct ns_dram_bank *)
((uintptr_t)&manifest->plat_dram.checksum +
sizeof(manifest->plat_dram.checksum));
manifest->plat_dram.banks = bank_ptr;
/* Calculate checksum of plat_dram structure */
checksum = num_banks + (uint64_t)bank_ptr;
/* Store FVP DRAM banks data in Boot Manifest */
for (unsigned long i = 0UL; i < num_banks; i++) {
uintptr_t base = FCONF_GET_PROPERTY(hw_config, dram_layout, dram_bank[i].base);
uint64_t size = FCONF_GET_PROPERTY(hw_config, dram_layout, dram_bank[i].size);
bank_ptr[i].base = base;
bank_ptr[i].size = size;
/* Update checksum */
checksum += base + size;
}
/* Checksum must be 0 */
manifest->plat_dram.checksum = ~checksum + 1UL;
return 0;
}
#endif /* ENABLE_RME */