/* * Copyright (c) 2018, ARM Limited and Contributors. All rights reserved. * * SPDX-License-Identifier: BSD-3-Clause */ #include #include #include #include #include #include #include "sq_mhu.h" /* SCP MHU secure channel registers */ #define SCP_INTR_S_STAT 0x200 #define SCP_INTR_S_SET 0x208 #define SCP_INTR_S_CLEAR 0x210 /* CPU MHU secure channel registers */ #define CPU_INTR_S_STAT 0x300 #define CPU_INTR_S_SET 0x308 #define CPU_INTR_S_CLEAR 0x310 DEFINE_BAKERY_LOCK(sq_lock); /* * Slot 31 is reserved because the MHU hardware uses this register bit to * indicate a non-secure access attempt. The total number of available slots is * therefore 31 [30:0]. */ #define MHU_MAX_SLOT_ID 30 void mhu_secure_message_start(unsigned int slot_id) { assert(slot_id <= MHU_MAX_SLOT_ID); bakery_lock_get(&sq_lock); /* Make sure any previous command has finished */ while (mmio_read_32(PLAT_SQ_MHU_BASE + CPU_INTR_S_STAT) & (1 << slot_id)) ; } void mhu_secure_message_send(unsigned int slot_id) { assert(slot_id <= MHU_MAX_SLOT_ID); assert(!(mmio_read_32(PLAT_SQ_MHU_BASE + CPU_INTR_S_STAT) & (1 << slot_id))); /* Send command to SCP */ mmio_write_32(PLAT_SQ_MHU_BASE + CPU_INTR_S_SET, 1 << slot_id); } uint32_t mhu_secure_message_wait(void) { uint32_t response; /* Wait for response from SCP */ while (!(response = mmio_read_32(PLAT_SQ_MHU_BASE + SCP_INTR_S_STAT))) ; return response; } void mhu_secure_message_end(unsigned int slot_id) { assert(slot_id <= MHU_MAX_SLOT_ID); /* * Clear any response we got by writing one in the relevant slot bit to * the CLEAR register */ mmio_write_32(PLAT_SQ_MHU_BASE + SCP_INTR_S_CLEAR, 1 << slot_id); bakery_lock_release(&sq_lock); } void mhu_secure_init(void) { bakery_lock_init(&sq_lock); /* * The STAT register resets to zero. Ensure it is in the expected state, * as a stale or garbage value would make us think it's a message we've * already sent. */ assert(mmio_read_32(PLAT_SQ_MHU_BASE + CPU_INTR_S_STAT) == 0); } void plat_sq_pwrc_setup(void) { mhu_secure_init(); }