/* * Copyright (c) 2017-2018, 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 #include #include #include "spm_private.h" /******************************************************************************* * Secure Partition context information. ******************************************************************************/ static sp_context_t sp_ctx; /******************************************************************************* * Set state of a Secure Partition context. ******************************************************************************/ void sp_state_set(sp_context_t *sp_ptr, sp_state_t state) { spin_lock(&(sp_ptr->state_lock)); sp_ptr->state = state; spin_unlock(&(sp_ptr->state_lock)); } /******************************************************************************* * Wait until the state of a Secure Partition is the specified one and change it * to the desired state. ******************************************************************************/ void sp_state_wait_switch(sp_context_t *sp_ptr, sp_state_t from, sp_state_t to) { int success = 0; while (success == 0) { spin_lock(&(sp_ptr->state_lock)); if (sp_ptr->state == from) { sp_ptr->state = to; success = 1; } spin_unlock(&(sp_ptr->state_lock)); } } /******************************************************************************* * Check if the state of a Secure Partition is the specified one and, if so, * change it to the desired state. Returns 0 on success, -1 on error. ******************************************************************************/ int sp_state_try_switch(sp_context_t *sp_ptr, sp_state_t from, sp_state_t to) { int ret = -1; spin_lock(&(sp_ptr->state_lock)); if (sp_ptr->state == from) { sp_ptr->state = to; ret = 0; } spin_unlock(&(sp_ptr->state_lock)); return ret; } /******************************************************************************* * This function takes an SP context pointer and prepares the CPU to enter. ******************************************************************************/ static void spm_sp_prepare_enter(sp_context_t *sp_ctx) { assert(sp_ctx != NULL); /* Assign the context of the SP to this CPU */ cm_set_context(&(sp_ctx->cpu_ctx), SECURE); /* Restore the context assigned above */ cm_el1_sysregs_context_restore(SECURE); cm_set_next_eret_context(SECURE); /* Invalidate TLBs at EL1. */ tlbivmalle1(); dsbish(); } /******************************************************************************* * Enter SP after preparing it with spm_sp_prepare_enter(). ******************************************************************************/ static uint64_t spm_sp_enter(sp_context_t *sp_ctx) { /* Enter Secure Partition */ return spm_secure_partition_enter(&sp_ctx->c_rt_ctx); } /******************************************************************************* * Jump to each Secure Partition for the first time. ******************************************************************************/ static int32_t spm_init(void) { uint64_t rc = 0; sp_context_t *ctx; INFO("Secure Partition init...\n"); ctx = &sp_ctx; ctx->state = SP_STATE_RESET; spm_sp_prepare_enter(ctx); rc |= spm_sp_enter(ctx); assert(rc == 0); ctx->state = SP_STATE_IDLE; INFO("Secure Partition initialized.\n"); return rc; } /******************************************************************************* * Initialize contexts of all Secure Partitions. ******************************************************************************/ int32_t spm_setup(void) { sp_context_t *ctx; /* Disable MMU at EL1 (initialized by BL2) */ disable_mmu_icache_el1(); /* Initialize context of the SP */ INFO("Secure Partition context setup start...\n"); ctx = &sp_ctx; /* Assign translation tables context. */ ctx->xlat_ctx_handle = spm_get_sp_xlat_context(); spm_sp_setup(ctx); /* Register init function for deferred init. */ bl31_register_bl32_init(&spm_init); INFO("Secure Partition setup done.\n"); return 0; } /******************************************************************************* * Secure Partition Manager SMC handler. ******************************************************************************/ uint64_t spm_smc_handler(uint32_t smc_fid, uint64_t x1, uint64_t x2, uint64_t x3, uint64_t x4, void *cookie, void *handle, uint64_t flags) { cpu_context_t *ns_cpu_context; unsigned int ns; /* Determine which security state this SMC originated from */ ns = is_caller_non_secure(flags); if (ns == SMC_FROM_SECURE) { /* Handle SMCs from Secure world. */ assert(handle == cm_get_context(SECURE)); /* Make next ERET jump to S-EL0 instead of S-EL1. */ cm_set_elr_spsr_el3(SECURE, read_elr_el1(), read_spsr_el1()); switch (smc_fid) { case SPM_VERSION_AARCH32: SMC_RET1(handle, SPM_VERSION_COMPILED); case SP_EVENT_COMPLETE_AARCH64: /* Save secure state */ cm_el1_sysregs_context_save(SECURE); if (sp_ctx.state == SP_STATE_RESET) { /* * SPM reports completion. The SPM must have * initiated the original request through a * synchronous entry into the secure * partition. Jump back to the original C * runtime context. */ spm_secure_partition_exit(sp_ctx.c_rt_ctx, x1); /* spm_secure_partition_exit doesn't return */ } /* Mark Secure Partition as idle */ assert(sp_ctx.state == SP_STATE_BUSY); sp_state_set(&sp_ctx, SP_STATE_IDLE); /* * This is the result from the Secure partition of an * earlier request. Copy the result into the non-secure * context and return to the non-secure state. */ /* Get a reference to the non-secure context */ ns_cpu_context = cm_get_context(NON_SECURE); assert(ns_cpu_context != NULL); /* Restore non-secure state */ cm_el1_sysregs_context_restore(NON_SECURE); cm_set_next_eret_context(NON_SECURE); /* Return to normal world */ SMC_RET1(ns_cpu_context, x1); case SP_MEMORY_ATTRIBUTES_GET_AARCH64: INFO("Received SP_MEMORY_ATTRIBUTES_GET_AARCH64 SMC\n"); if (sp_ctx.state != SP_STATE_RESET) { WARN("SP_MEMORY_ATTRIBUTES_GET_AARCH64 is available at boot time only\n"); SMC_RET1(handle, SPM_NOT_SUPPORTED); } SMC_RET1(handle, spm_memory_attributes_get_smc_handler( &sp_ctx, x1)); case SP_MEMORY_ATTRIBUTES_SET_AARCH64: INFO("Received SP_MEMORY_ATTRIBUTES_SET_AARCH64 SMC\n"); if (sp_ctx.state != SP_STATE_RESET) { WARN("SP_MEMORY_ATTRIBUTES_SET_AARCH64 is available at boot time only\n"); SMC_RET1(handle, SPM_NOT_SUPPORTED); } SMC_RET1(handle, spm_memory_attributes_set_smc_handler( &sp_ctx, x1, x2, x3)); default: break; } } else { /* Handle SMCs from Non-secure world. */ switch (smc_fid) { case MM_VERSION_AARCH32: SMC_RET1(handle, MM_VERSION_COMPILED); case MM_COMMUNICATE_AARCH32: case MM_COMMUNICATE_AARCH64: { uint64_t mm_cookie = x1; uint64_t comm_buffer_address = x2; uint64_t comm_size_address = x3; /* Cookie. Reserved for future use. It must be zero. */ if (mm_cookie != 0U) { ERROR("MM_COMMUNICATE: cookie is not zero\n"); SMC_RET1(handle, SPM_INVALID_PARAMETER); } if (comm_buffer_address == 0U) { ERROR("MM_COMMUNICATE: comm_buffer_address is zero\n"); SMC_RET1(handle, SPM_INVALID_PARAMETER); } if (comm_size_address != 0U) { VERBOSE("MM_COMMUNICATE: comm_size_address is not 0 as recommended.\n"); } /* Save the Normal world context */ cm_el1_sysregs_context_save(NON_SECURE); /* * Wait until the state of the Secure Partition is IDLE * and set it to BUSY */ sp_state_wait_switch(&sp_ctx, SP_STATE_IDLE, SP_STATE_BUSY); /* Jump to the Secure Partition. */ spm_sp_prepare_enter(&sp_ctx); SMC_RET4(&(sp_ctx.cpu_ctx), smc_fid, comm_buffer_address, comm_size_address, plat_my_core_pos()); } case SP_MEMORY_ATTRIBUTES_GET_AARCH64: case SP_MEMORY_ATTRIBUTES_SET_AARCH64: /* SMC interfaces reserved for secure callers. */ SMC_RET1(handle, SPM_NOT_SUPPORTED); default: break; } } SMC_RET1(handle, SMC_UNK); }