Djam/arm-trusted-firmware
1
0
Fork 0
mirror of https://github.com/ARM-software/arm-trusted-firmware.git synced 2025-04-27 23:35:10 +00:00
Code Issues Projects Releases Packages Wiki Activity Actions
arm-trusted-firmware/bl32/sp_min/aarch32/entrypoint.S
David Cunado 18f2efd67d Fully initialise essential control registers 
This patch updates the el3_arch_init_common macro so that it fully
initialises essential control registers rather then relying on hardware
to set the reset values.

The context management functions are also updated to fully initialise
the appropriate control registers when initialising the non-secure and
secure context structures and when preparing to leave EL3 for a lower
EL.

This gives better alignement with the ARM ARM which states that software
must initialise RES0 and RES1 fields with 0 / 1.

This patch also corrects the following typos:

"NASCR definitions" -> "NSACR definitions"

Change-Id: Ia8940b8351dc27bc09e2138b011e249655041cfc
Signed-off-by: David Cunado <david.cunado@arm.com>
2017-06-21 17:57:54 +01:00

238 lines
7.1 KiB
ArmAsm
Raw Blame History

/*
* Copyright (c) 2016-2017, ARM Limited and Contributors. All rights reserved.
*
* SPDX-License-Identifier: BSD-3-Clause
*/
#include <arch.h>
#include <asm_macros.S>
#include <bl_common.h>
#include <context.h>
#include <el3_common_macros.S>
#include <runtime_svc.h>
#include <smcc_helpers.h>
#include <smcc_macros.S>
#include <xlat_tables_defs.h>
.globl sp_min_vector_table
.globl sp_min_entrypoint
.globl sp_min_warm_entrypoint
vector_base sp_min_vector_table
b sp_min_entrypoint
b plat_panic_handler /* Undef */
b handle_smc /* Syscall */
b plat_panic_handler /* Prefetch abort */
b plat_panic_handler /* Data abort */
b plat_panic_handler /* Reserved */
b plat_panic_handler /* IRQ */
b plat_panic_handler /* FIQ */
/*
* The Cold boot/Reset entrypoint for SP_MIN
*/
func sp_min_entrypoint
#if !RESET_TO_SP_MIN
/* ---------------------------------------------------------------
* Preceding bootloader has populated r0 with a pointer to a
* 'bl_params_t' structure & r1 with a pointer to platform
* specific structure
* ---------------------------------------------------------------
*/
mov r11, r0
mov r12, r1
/* ---------------------------------------------------------------------
* For !RESET_TO_SP_MIN systems, only the primary CPU ever reaches
* sp_min_entrypoint() during the cold boot flow, so the cold/warm boot
* and primary/secondary CPU logic should not be executed in this case.
*
* Also, assume that the previous bootloader has already initialised the
* SCTLR, including the CPU endianness, and has initialised the memory.
* ---------------------------------------------------------------------
*/
el3_entrypoint_common \
_init_sctlr=0 \
_warm_boot_mailbox=0 \
_secondary_cold_boot=0 \
_init_memory=0 \
_init_c_runtime=1 \
_exception_vectors=sp_min_vector_table
/* ---------------------------------------------------------------------
* Relay the previous bootloader's arguments to the platform layer
* ---------------------------------------------------------------------
*/
mov r0, r11
mov r1, r12
#else
/* ---------------------------------------------------------------------
* For RESET_TO_SP_MIN systems which have a programmable reset address,
* sp_min_entrypoint() is executed only on the cold boot path so we can
* skip the warm boot mailbox mechanism.
* ---------------------------------------------------------------------
*/
el3_entrypoint_common \
_init_sctlr=1 \
_warm_boot_mailbox=!PROGRAMMABLE_RESET_ADDRESS \
_secondary_cold_boot=!COLD_BOOT_SINGLE_CPU \
_init_memory=1 \
_init_c_runtime=1 \
_exception_vectors=sp_min_vector_table
/* ---------------------------------------------------------------------
* For RESET_TO_SP_MIN systems, BL32 (SP_MIN) is the first bootloader
* to run so there's no argument to relay from a previous bootloader.
* Zero the arguments passed to the platform layer to reflect that.
* ---------------------------------------------------------------------
*/
mov r0, #0
mov r1, #0
#endif /* RESET_TO_SP_MIN */
bl sp_min_early_platform_setup
bl sp_min_plat_arch_setup
/* Jump to the main function */
bl sp_min_main
/* -------------------------------------------------------------
* Clean the .data & .bss sections to main memory. This ensures
* that any global data which was initialised by the primary CPU
* is visible to secondary CPUs before they enable their data
* caches and participate in coherency.
* -------------------------------------------------------------
*/
ldr r0, =__DATA_START__
ldr r1, =__DATA_END__
sub r1, r1, r0
bl clean_dcache_range
ldr r0, =__BSS_START__
ldr r1, =__BSS_END__
sub r1, r1, r0
bl clean_dcache_range
bl smc_get_next_ctx
/* r0 points to `smc_ctx_t` */
/* The PSCI cpu_context registers have been copied to `smc_ctx_t` */
b sp_min_exit
endfunc sp_min_entrypoint
/*
* SMC handling function for SP_MIN.
*/
func handle_smc
/* On SMC entry, `sp` points to `smc_ctx_t`. Save `lr`. */
str lr, [sp, #SMC_CTX_LR_MON]
smcc_save_gp_mode_regs
/*
* `sp` still points to `smc_ctx_t`. Save it to a register
* and restore the C runtime stack pointer to `sp`.
*/
mov r2, sp /* handle */
ldr sp, [r2, #SMC_CTX_SP_MON]
ldr r0, [r2, #SMC_CTX_SCR]
and r3, r0, #SCR_NS_BIT /* flags */
/* Switch to Secure Mode*/
bic r0, #SCR_NS_BIT
stcopr r0, SCR
isb
ldr r0, [r2, #SMC_CTX_GPREG_R0] /* smc_fid */
/* Check whether an SMC64 is issued */
tst r0, #(FUNCID_CC_MASK << FUNCID_CC_SHIFT)
beq 1f
/* SMC32 is not detected. Return error back to caller */
mov r0, #SMC_UNK
str r0, [r2, #SMC_CTX_GPREG_R0]
mov r0, r2
b sp_min_exit
1:
/* SMC32 is detected */
mov r1, #0 /* cookie */
bl handle_runtime_svc
/* `r0` points to `smc_ctx_t` */
b sp_min_exit
endfunc handle_smc
/*
* The Warm boot entrypoint for SP_MIN.
*/
func sp_min_warm_entrypoint
/*
* On the warm boot path, most of the EL3 initialisations performed by
* 'el3_entrypoint_common' must be skipped:
*
* - Only when the platform bypasses the BL1/BL32 (SP_MIN) entrypoint by
* programming the reset address do we need to initialied the SCTLR.
* In other cases, we assume this has been taken care by the
* entrypoint code.
*
* - No need to determine the type of boot, we know it is a warm boot.
*
* - Do not try to distinguish between primary and secondary CPUs, this
* notion only exists for a cold boot.
*
* - No need to initialise the memory or the C runtime environment,
* it has been done once and for all on the cold boot path.
*/
el3_entrypoint_common \
_init_sctlr=PROGRAMMABLE_RESET_ADDRESS \
_warm_boot_mailbox=0 \
_secondary_cold_boot=0 \
_init_memory=0 \
_init_c_runtime=0 \
_exception_vectors=sp_min_vector_table
/*
* We're about to enable MMU and participate in PSCI state coordination.
*
* The PSCI implementation invokes platform routines that enable CPUs to
* participate in coherency. On a system where CPUs are not
* cache-coherent without appropriate platform specific programming,
* having caches enabled until such time might lead to coherency issues
* (resulting from stale data getting speculatively fetched, among
* others). Therefore we keep data caches disabled even after enabling
* the MMU for such platforms.
*
* On systems with hardware-assisted coherency, or on single cluster
* platforms, such platform specific programming is not required to
* enter coherency (as CPUs already are); and there's no reason to have
* caches disabled either.
*/
mov r0, #DISABLE_DCACHE
bl bl32_plat_enable_mmu
#if HW_ASSISTED_COHERENCY || WARMBOOT_ENABLE_DCACHE_EARLY
ldcopr r0, SCTLR
orr r0, r0, #SCTLR_C_BIT
stcopr r0, SCTLR
isb
#endif
bl sp_min_warm_boot
bl smc_get_next_ctx
/* r0 points to `smc_ctx_t` */
/* The PSCI cpu_context registers have been copied to `smc_ctx_t` */
b sp_min_exit
endfunc sp_min_warm_entrypoint
/*
* The function to restore the registers from SMC context and return
* to the mode restored to SPSR.
*
* Arguments : r0 must point to the SMC context to restore from.
*/
func sp_min_exit
monitor_exit
endfunc sp_min_exit
Reference in a new issue View git blame Copy permalink