/* * Copyright (c) 2013-2024, 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 "tsp_private.h" #include /******************************************************************************* * TSP main entry point where it gets the opportunity to initialize its secure * state/applications. Once the state is initialized, it must return to the * SPD with a pointer to the 'tsp_vector_table' jump table. ******************************************************************************/ uint64_t tsp_main(void) { NOTICE("TSP: %s\n", build_version_string); NOTICE("TSP: %s\n", build_message); INFO("TSP: Total memory base : 0x%lx\n", (unsigned long) BL32_BASE); INFO("TSP: Total memory size : 0x%lx bytes\n", BL32_TOTAL_SIZE); uint32_t linear_id = plat_my_core_pos(); /* Initialize the platform */ tsp_platform_setup(); /* Initialize secure/applications state here */ tsp_generic_timer_start(); /* Update this cpu's statistics */ tsp_stats[linear_id].smc_count++; tsp_stats[linear_id].eret_count++; tsp_stats[linear_id].cpu_on_count++; INFO("TSP: cpu 0x%lx: %d smcs, %d erets %d cpu on requests\n", read_mpidr(), tsp_stats[linear_id].smc_count, tsp_stats[linear_id].eret_count, tsp_stats[linear_id].cpu_on_count); console_flush(); return (uint64_t) &tsp_vector_table; } /******************************************************************************* * This function performs any remaining book keeping in the test secure payload * after this cpu's architectural state has been setup in response to an earlier * psci cpu_on request. ******************************************************************************/ smc_args_t *tsp_cpu_on_main(void) { uint32_t linear_id = plat_my_core_pos(); /* Initialize secure/applications state here */ tsp_generic_timer_start(); /* Update this cpu's statistics */ tsp_stats[linear_id].smc_count++; tsp_stats[linear_id].eret_count++; tsp_stats[linear_id].cpu_on_count++; INFO("TSP: cpu 0x%lx turned on\n", read_mpidr()); INFO("TSP: cpu 0x%lx: %d smcs, %d erets %d cpu on requests\n", read_mpidr(), tsp_stats[linear_id].smc_count, tsp_stats[linear_id].eret_count, tsp_stats[linear_id].cpu_on_count); /* Indicate to the SPD that we have completed turned ourselves on */ return set_smc_args(TSP_ON_DONE, 0, 0, 0, 0, 0, 0, 0); } /******************************************************************************* * This function performs any remaining book keeping in the test secure payload * before this cpu is turned off in response to a psci cpu_off request. ******************************************************************************/ smc_args_t *tsp_cpu_off_main(uint64_t arg0, uint64_t arg1, uint64_t arg2, uint64_t arg3, uint64_t arg4, uint64_t arg5, uint64_t arg6, uint64_t arg7) { uint32_t linear_id = plat_my_core_pos(); /* * This cpu is being turned off, so disable the timer to prevent the * secure timer interrupt from interfering with power down. A pending * interrupt will be lost but we do not care as we are turning off. */ tsp_generic_timer_stop(); /* Update this cpu's statistics */ tsp_stats[linear_id].smc_count++; tsp_stats[linear_id].eret_count++; tsp_stats[linear_id].cpu_off_count++; INFO("TSP: cpu 0x%lx off request\n", read_mpidr()); INFO("TSP: cpu 0x%lx: %d smcs, %d erets %d cpu off requests\n", read_mpidr(), tsp_stats[linear_id].smc_count, tsp_stats[linear_id].eret_count, tsp_stats[linear_id].cpu_off_count); /* Indicate to the SPD that we have completed this request */ return set_smc_args(TSP_OFF_DONE, 0, 0, 0, 0, 0, 0, 0); } /******************************************************************************* * This function performs any book keeping in the test secure payload before * this cpu's architectural state is saved in response to an earlier psci * cpu_suspend request. ******************************************************************************/ smc_args_t *tsp_cpu_suspend_main(uint64_t arg0, uint64_t arg1, uint64_t arg2, uint64_t arg3, uint64_t arg4, uint64_t arg5, uint64_t arg6, uint64_t arg7) { uint32_t linear_id = plat_my_core_pos(); /* * Save the time context and disable it to prevent the secure timer * interrupt from interfering with wakeup from the suspend state. */ tsp_generic_timer_save(); tsp_generic_timer_stop(); /* Update this cpu's statistics */ tsp_stats[linear_id].smc_count++; tsp_stats[linear_id].eret_count++; tsp_stats[linear_id].cpu_suspend_count++; INFO("TSP: cpu 0x%lx: %d smcs, %d erets %d cpu suspend requests\n", read_mpidr(), tsp_stats[linear_id].smc_count, tsp_stats[linear_id].eret_count, tsp_stats[linear_id].cpu_suspend_count); /* Indicate to the SPD that we have completed this request */ return set_smc_args(TSP_SUSPEND_DONE, 0, 0, 0, 0, 0, 0, 0); } /******************************************************************************* * This function performs any book keeping in the test secure payload after this * cpu's architectural state has been restored after wakeup from an earlier psci * cpu_suspend request. ******************************************************************************/ smc_args_t *tsp_cpu_resume_main(uint64_t max_off_pwrlvl, uint64_t arg1, uint64_t arg2, uint64_t arg3, uint64_t arg4, uint64_t arg5, uint64_t arg6, uint64_t arg7) { uint32_t linear_id = plat_my_core_pos(); /* Restore the generic timer context */ tsp_generic_timer_restore(); /* Update this cpu's statistics */ tsp_stats[linear_id].smc_count++; tsp_stats[linear_id].eret_count++; tsp_stats[linear_id].cpu_resume_count++; INFO("TSP: cpu 0x%lx resumed. maximum off power level %" PRId64 "\n", read_mpidr(), max_off_pwrlvl); INFO("TSP: cpu 0x%lx: %d smcs, %d erets %d cpu resume requests\n", read_mpidr(), tsp_stats[linear_id].smc_count, tsp_stats[linear_id].eret_count, tsp_stats[linear_id].cpu_resume_count); /* Indicate to the SPD that we have completed this request */ return set_smc_args(TSP_RESUME_DONE, 0, 0, 0, 0, 0, 0, 0); } /******************************************************************************* * TSP fast smc handler. The secure monitor jumps to this function by * doing the ERET after populating X0-X7 registers. The arguments are received * in the function arguments in order. Once the service is rendered, this * function returns to Secure Monitor by raising SMC. ******************************************************************************/ smc_args_t *tsp_smc_handler(uint64_t func, uint64_t arg1, uint64_t arg2, uint64_t arg3, uint64_t arg4, uint64_t arg5, uint64_t arg6, uint64_t arg7) { uint128_t service_args; uint64_t service_arg0; uint64_t service_arg1; uint64_t results[2]; uint32_t linear_id = plat_my_core_pos(); u_register_t dit; /* Update this cpu's statistics */ tsp_stats[linear_id].smc_count++; tsp_stats[linear_id].eret_count++; INFO("TSP: cpu 0x%lx received %s smc 0x%" PRIx64 "\n", read_mpidr(), ((func >> 31) & 1) == 1 ? "fast" : "yielding", func); INFO("TSP: cpu 0x%lx: %d smcs, %d erets\n", read_mpidr(), tsp_stats[linear_id].smc_count, tsp_stats[linear_id].eret_count); /* Render secure services and obtain results here */ results[0] = arg1; results[1] = arg2; /* * Request a service back from dispatcher/secure monitor. * This call returns and thereafter resumes execution. */ service_args = tsp_get_magic(); service_arg0 = (uint64_t)service_args; service_arg1 = (uint64_t)(service_args >> 64U); /* * Write a dummy value to an MTE2 register, to simulate usage in the * secure world */ if (is_feat_mte2_supported()) { write_gcr_el1(0x99); } /* Determine the function to perform based on the function ID */ switch (TSP_BARE_FID(func)) { case TSP_ADD: results[0] += service_arg0; results[1] += service_arg1; break; case TSP_SUB: results[0] -= service_arg0; results[1] -= service_arg1; break; case TSP_MUL: results[0] *= service_arg0; results[1] *= service_arg1; break; case TSP_DIV: results[0] /= service_arg0 ? service_arg0 : 1; results[1] /= service_arg1 ? service_arg1 : 1; break; case TSP_CHECK_DIT: if (!is_feat_dit_supported()) { ERROR("DIT not supported\n"); results[0] = 0; results[1] = 0xffff; break; } dit = read_dit(); results[0] = dit == service_arg0; results[1] = dit; /* Toggle the dit bit */ write_dit(service_arg0 != 0U ? 0 : DIT_BIT); break; case TSP_MODIFY_EL1_CTX: /* * Write dummy values to EL1 context registers, to simulate * their usage in the secure world. */ if (arg1 == TSP_CORRUPT_EL1_REGS) { modify_el1_ctx_regs(TSP_CORRUPT_EL1_REGS); } else { modify_el1_ctx_regs(TSP_RESTORE_EL1_REGS); } break; default: break; } return set_smc_args(func, 0, results[0], results[1], 0, 0, 0, 0); }