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/*
* Copyright (c) 2013-2018, ARM Limited and Contributors. All rights reserved.
*
* SPDX-License-Identifier: BSD-3-Clause
*/
#ifndef __TSPD_PRIVATE_H__
#define __TSPD_PRIVATE_H__
#include <arch.h>
#include <context.h>
#include <interrupt_mgmt.h>
#include <platform_def.h>
#include <psci.h>
/*******************************************************************************
* Secure Payload PM state information e.g. SP is suspended, uninitialised etc
* and macros to access the state information in the per-cpu 'state' flags
******************************************************************************/
#define TSP_PSTATE_OFF 0
#define TSP_PSTATE_ON 1
#define TSP_PSTATE_SUSPEND 2
#define TSP_PSTATE_SHIFT 0
#define TSP_PSTATE_MASK 0x3
#define get_tsp_pstate(state) ((state >> TSP_PSTATE_SHIFT) & TSP_PSTATE_MASK)
#define clr_tsp_pstate(state) (state &= ~(TSP_PSTATE_MASK \
<< TSP_PSTATE_SHIFT))
#define set_tsp_pstate(st, pst) do { \
clr_tsp_pstate(st); \
st |= (pst & TSP_PSTATE_MASK) << \
TSP_PSTATE_SHIFT; \
} while (0);
/*
* This flag is used by the TSPD to determine if the TSP is servicing a yielding
* SMC request prior to programming the next entry into the TSP e.g. if TSP
* execution is preempted by a non-secure interrupt and handed control to the
* normal world. If another request which is distinct from what the TSP was
* previously doing arrives, then this flag will be help the TSPD to either
* reject the new request or service it while ensuring that the previous context
* is not corrupted.
*/
#define YIELD_SMC_ACTIVE_FLAG_SHIFT 2
#define YIELD_SMC_ACTIVE_FLAG_MASK 1
#define get_yield_smc_active_flag(state) \
((state >> YIELD_SMC_ACTIVE_FLAG_SHIFT) \
& YIELD_SMC_ACTIVE_FLAG_MASK)
#define set_yield_smc_active_flag(state) (state |= \
1 << YIELD_SMC_ACTIVE_FLAG_SHIFT)
#define clr_yield_smc_active_flag(state) (state &= \
~(YIELD_SMC_ACTIVE_FLAG_MASK \
<< YIELD_SMC_ACTIVE_FLAG_SHIFT))
/*******************************************************************************
* Secure Payload execution state information i.e. aarch32 or aarch64
******************************************************************************/
#define TSP_AARCH32 MODE_RW_32
#define TSP_AARCH64 MODE_RW_64
/*******************************************************************************
* The SPD should know the type of Secure Payload.
******************************************************************************/
#define TSP_TYPE_UP PSCI_TOS_NOT_UP_MIG_CAP
#define TSP_TYPE_UPM PSCI_TOS_UP_MIG_CAP
#define TSP_TYPE_MP PSCI_TOS_NOT_PRESENT_MP
/*******************************************************************************
* Secure Payload migrate type information as known to the SPD. We assume that
* the SPD is dealing with an MP Secure Payload.
******************************************************************************/
#define TSP_MIGRATE_INFO TSP_TYPE_MP
/*******************************************************************************
* Number of cpus that the present on this platform. TODO: Rely on a topology
* tree to determine this in the future to avoid assumptions about mpidr
* allocation
******************************************************************************/
#define TSPD_CORE_COUNT PLATFORM_CORE_COUNT
/*******************************************************************************
* Constants that allow assembler code to preserve callee-saved registers of the
* C runtime context while performing a security state switch.
******************************************************************************/
#define TSPD_C_RT_CTX_X19 0x0
#define TSPD_C_RT_CTX_X20 0x8
#define TSPD_C_RT_CTX_X21 0x10
#define TSPD_C_RT_CTX_X22 0x18
#define TSPD_C_RT_CTX_X23 0x20
#define TSPD_C_RT_CTX_X24 0x28
#define TSPD_C_RT_CTX_X25 0x30
#define TSPD_C_RT_CTX_X26 0x38
#define TSPD_C_RT_CTX_X27 0x40
#define TSPD_C_RT_CTX_X28 0x48
#define TSPD_C_RT_CTX_X29 0x50
#define TSPD_C_RT_CTX_X30 0x58
#define TSPD_C_RT_CTX_SIZE 0x60
#define TSPD_C_RT_CTX_ENTRIES (TSPD_C_RT_CTX_SIZE >> DWORD_SHIFT)
/*******************************************************************************
* Constants that allow assembler code to preserve caller-saved registers of the
* SP context while performing a TSP preemption.
* Note: These offsets have to match with the offsets for the corresponding
* registers in cpu_context as we are using memcpy to copy the values from
* cpu_context to sp_ctx.
******************************************************************************/
#define TSPD_SP_CTX_X0 0x0
#define TSPD_SP_CTX_X1 0x8
#define TSPD_SP_CTX_X2 0x10
#define TSPD_SP_CTX_X3 0x18
#define TSPD_SP_CTX_X4 0x20
#define TSPD_SP_CTX_X5 0x28
#define TSPD_SP_CTX_X6 0x30
#define TSPD_SP_CTX_X7 0x38
#define TSPD_SP_CTX_X8 0x40
#define TSPD_SP_CTX_X9 0x48
#define TSPD_SP_CTX_X10 0x50
#define TSPD_SP_CTX_X11 0x58
#define TSPD_SP_CTX_X12 0x60
#define TSPD_SP_CTX_X13 0x68
#define TSPD_SP_CTX_X14 0x70
#define TSPD_SP_CTX_X15 0x78
#define TSPD_SP_CTX_X16 0x80
#define TSPD_SP_CTX_X17 0x88
#define TSPD_SP_CTX_SIZE 0x90
#define TSPD_SP_CTX_ENTRIES (TSPD_SP_CTX_SIZE >> DWORD_SHIFT)
#ifndef __ASSEMBLY__
#include <cassert.h>
#include <stdint.h>
/*
* The number of arguments to save during a SMC call for TSP.
* Currently only x1 and x2 are used by TSP.
*/
#define TSP_NUM_ARGS 0x2
/* AArch64 callee saved general purpose register context structure. */
DEFINE_REG_STRUCT(c_rt_regs, TSPD_C_RT_CTX_ENTRIES);
/*
* Compile time assertion to ensure that both the compiler and linker
* have the same double word aligned view of the size of the C runtime
* register context.
*/
CASSERT(TSPD_C_RT_CTX_SIZE == sizeof(c_rt_regs_t), \
assert_spd_c_rt_regs_size_mismatch);
/* SEL1 Secure payload (SP) caller saved register context structure. */
DEFINE_REG_STRUCT(sp_ctx_regs, TSPD_SP_CTX_ENTRIES);
/*
* Compile time assertion to ensure that both the compiler and linker
* have the same double word aligned view of the size of the C runtime
* register context.
*/
CASSERT(TSPD_SP_CTX_SIZE == sizeof(sp_ctx_regs_t), \
assert_spd_sp_regs_size_mismatch);
/*******************************************************************************
* Structure which helps the SPD to maintain the per-cpu state of the SP.
* 'saved_spsr_el3' - temporary copy to allow S-EL1 interrupt handling when
* the TSP has been preempted.
* 'saved_elr_el3' - temporary copy to allow S-EL1 interrupt handling when
* the TSP has been preempted.
* 'state' - collection of flags to track SP state e.g. on/off
* 'mpidr' - mpidr to associate a context with a cpu
* 'c_rt_ctx' - stack address to restore C runtime context from after
* returning from a synchronous entry into the SP.
* 'cpu_ctx' - space to maintain SP architectural state
* 'saved_tsp_args' - space to store arguments for TSP arithmetic operations
* which will queried using the TSP_GET_ARGS SMC by TSP.
* 'sp_ctx' - space to save the SEL1 Secure Payload(SP) caller saved
* register context after it has been preempted by an EL3
* routed NS interrupt and when a Secure Interrupt is taken
* to SP.
******************************************************************************/
typedef struct tsp_context {
uint64_t saved_elr_el3;
uint32_t saved_spsr_el3;
uint32_t state;
uint64_t mpidr;
uint64_t c_rt_ctx;
cpu_context_t cpu_ctx;
uint64_t saved_tsp_args[TSP_NUM_ARGS];
#if TSP_NS_INTR_ASYNC_PREEMPT
sp_ctx_regs_t sp_ctx;
#endif
} tsp_context_t;
/* Helper macros to store and retrieve tsp args from tsp_context */
#define store_tsp_args(tsp_ctx, x1, x2) do {\
tsp_ctx->saved_tsp_args[0] = x1;\
tsp_ctx->saved_tsp_args[1] = x2;\
} while (0)
#define get_tsp_args(tsp_ctx, x1, x2) do {\
x1 = tsp_ctx->saved_tsp_args[0];\
x2 = tsp_ctx->saved_tsp_args[1];\
} while (0)
/* TSPD power management handlers */
extern const spd_pm_ops_t tspd_pm;
/*******************************************************************************
* Forward declarations
******************************************************************************/
typedef struct tsp_vectors tsp_vectors_t;
/*******************************************************************************
* Function & Data prototypes
******************************************************************************/
uint64_t tspd_enter_sp(uint64_t *c_rt_ctx);
void __dead2 tspd_exit_sp(uint64_t c_rt_ctx, uint64_t ret);
uint64_t tspd_synchronous_sp_entry(tsp_context_t *tsp_ctx);
void __dead2 tspd_synchronous_sp_exit(tsp_context_t *tsp_ctx, uint64_t ret);
void tspd_init_tsp_ep_state(struct entry_point_info *tsp_entry_point,
uint32_t rw,
uint64_t pc,
tsp_context_t *tsp_ctx);
int tspd_abort_preempted_smc(tsp_context_t *tsp_ctx);
uint64_t tspd_handle_sp_preemption(void *handle);
extern tsp_context_t tspd_sp_context[TSPD_CORE_COUNT];
extern tsp_vectors_t *tsp_vectors;
#endif /*__ASSEMBLY__*/
#endif /* __TSPD_PRIVATE_H__ */