/* * Copyright (c) 2013-2020, Arm Limited and Contributors. All rights reserved. * Copyright (c) 2019-2022, Xilinx, Inc. All rights reserved. * Copyright (c) 2022-2023, Advanced Micro Devices, Inc. All rights reserved. * * SPDX-License-Identifier: BSD-3-Clause */ #include #include #include #include #include #include #include #include #include "pm_defs.h" #include "pm_ipi.h" #define ERROR_CODE_MASK (0xFFFFU) #define PM_OFFSET (0U) /* * ARM v8.2, the cache will turn off automatically when cpu * power down. Therefore, there is no doubt to use the spin_lock here. */ #if !HW_ASSISTED_COHERENCY DEFINE_BAKERY_LOCK(pm_secure_lock); static inline void pm_ipi_lock_get(void) { bakery_lock_get(&pm_secure_lock); } static inline void pm_ipi_lock_release(void) { bakery_lock_release(&pm_secure_lock); } #else spinlock_t pm_secure_lock; static inline void pm_ipi_lock_get(void) { spin_lock(&pm_secure_lock); } static inline void pm_ipi_lock_release(void) { spin_unlock(&pm_secure_lock); } #endif /** * pm_ipi_init() - Initialize IPI peripheral for communication with * remote processor. * @proc: Pointer to the processor who is initiating request. * * Return: On success, the initialization function must return 0. * Any other return value will cause the framework to ignore * the service. * * Called from pm_setup initialization function. */ void pm_ipi_init(const struct pm_proc *proc) { ipi_mb_open(proc->ipi->local_ipi_id, proc->ipi->remote_ipi_id); } /** * pm_ipi_send_common() - Sends IPI request to the remote processor. * @proc: Pointer to the processor who is initiating request. * @payload: API id and call arguments to be written in IPI buffer. * @is_blocking: if to trigger the notification in blocking mode or not. * * Send an IPI request to the power controller. Caller needs to hold * the 'pm_secure_lock' lock. * * Return: Returns status, either success or error+reason. * */ static enum pm_ret_status pm_ipi_send_common(const struct pm_proc *proc, uint32_t payload[PAYLOAD_ARG_CNT], uint32_t is_blocking) { uint32_t offset = PM_OFFSET; uintptr_t buffer_base = proc->ipi->buffer_base + IPI_BUFFER_TARGET_REMOTE_OFFSET + IPI_BUFFER_REQ_OFFSET; #if IPI_CRC_CHECK payload[PAYLOAD_CRC_POS] = calculate_crc(payload, IPI_W0_TO_W6_SIZE); #endif /* Write payload into IPI buffer */ for (size_t i = 0; i < PAYLOAD_ARG_CNT; i++) { mmio_write_32(buffer_base + offset, payload[i]); offset += PAYLOAD_ARG_SIZE; } /* Generate IPI to remote processor */ ipi_mb_notify(proc->ipi->local_ipi_id, proc->ipi->remote_ipi_id, is_blocking); return PM_RET_SUCCESS; } /** * pm_ipi_send_non_blocking() - Sends IPI request to the remote processor * without blocking notification. * @proc: Pointer to the processor who is initiating request. * @payload: API id and call arguments to be written in IPI buffer. * * Send an IPI request to the power controller. * * Return: Returns status, either success or error+reason. * */ enum pm_ret_status pm_ipi_send_non_blocking(const struct pm_proc *proc, uint32_t payload[PAYLOAD_ARG_CNT]) { enum pm_ret_status ret; pm_ipi_lock_get(); ret = pm_ipi_send_common(proc, payload, IPI_NON_BLOCKING); pm_ipi_lock_release(); return ret; } /** * pm_ipi_send() - Sends IPI request to the remote processor. * @proc: Pointer to the processor who is initiating request. * @payload: API id and call arguments to be written in IPI buffer. * * Send an IPI request to the power controller. * * Return: Returns status, either success or error+reason. * */ enum pm_ret_status pm_ipi_send(const struct pm_proc *proc, uint32_t payload[PAYLOAD_ARG_CNT]) { enum pm_ret_status ret; pm_ipi_lock_get(); ret = pm_ipi_send_common(proc, payload, IPI_BLOCKING); pm_ipi_lock_release(); return ret; } /** * pm_ipi_buff_read() - Reads IPI response after remote processor has handled * interrupt. * @proc: Pointer to the processor who is waiting and reading response. * @value: Used to return value from IPI buffer element (optional). * @count: Number of values to return in @value. * * Return: Returns status, either success or error+reason. * */ static enum pm_ret_status pm_ipi_buff_read(const struct pm_proc *proc, uint32_t *value, size_t count) { size_t i; enum pm_ret_status ret; #if IPI_CRC_CHECK uint32_t *payload_ptr = value; size_t j; uint32_t response_payload[PAYLOAD_ARG_CNT]; #endif uintptr_t buffer_base = proc->ipi->buffer_base + IPI_BUFFER_TARGET_REMOTE_OFFSET + IPI_BUFFER_RESP_OFFSET; /* * Read response from IPI buffer * buf-0: success or error+reason * buf-1: value * buf-2: unused * buf-3: unused */ for (i = 1; i <= count; i++) { *value = mmio_read_32(buffer_base + (i * PAYLOAD_ARG_SIZE)); value++; } ret = mmio_read_32(buffer_base); #if IPI_CRC_CHECK for (j = 0; j < PAYLOAD_ARG_CNT; j++) { response_payload[j] = mmio_read_32(buffer_base + (j * PAYLOAD_ARG_SIZE)); } if (response_payload[PAYLOAD_CRC_POS] != calculate_crc(response_payload, IPI_W0_TO_W6_SIZE)) { NOTICE("ERROR in CRC response payload value:0x%x\n", response_payload[PAYLOAD_CRC_POS]); ret = PM_RET_ERROR_INVALID_CRC; /* Payload data is invalid as CRC validation failed * Clear the payload to avoid leakage of data to upper layers */ memset(payload_ptr, 0, count); } #endif return ret; } /** * pm_ipi_buff_read_callb() - Callback function that reads value from * ipi response buffer. * @value: Used to return value from IPI buffer element. * @count: Number of values to return in @value. * * This callback function fills requested data in @value from ipi response * buffer. * * Return: Returns status, either success or error. * */ enum pm_ret_status pm_ipi_buff_read_callb(uint32_t *value, size_t count) { size_t i; #if IPI_CRC_CHECK uint32_t *payload_ptr = value; size_t j; unsigned int response_payload[PAYLOAD_ARG_CNT] = {0}; #endif uintptr_t buffer_base = IPI_BUFFER_REMOTE_BASE + IPI_BUFFER_TARGET_LOCAL_OFFSET + IPI_BUFFER_REQ_OFFSET; enum pm_ret_status ret = PM_RET_SUCCESS; if (count > IPI_BUFFER_MAX_WORDS) { count = IPI_BUFFER_MAX_WORDS; } for (i = 0; i <= count; i++) { *value = mmio_read_32(buffer_base + (i * PAYLOAD_ARG_SIZE)); value++; } #if IPI_CRC_CHECK for (j = 0; j < PAYLOAD_ARG_CNT; j++) { response_payload[j] = mmio_read_32(buffer_base + (j * PAYLOAD_ARG_SIZE)); } if (response_payload[PAYLOAD_CRC_POS] != calculate_crc(response_payload, IPI_W0_TO_W6_SIZE)) { NOTICE("ERROR in CRC response payload value:0x%x\n", response_payload[PAYLOAD_CRC_POS]); ret = PM_RET_ERROR_INVALID_CRC; /* Payload data is invalid as CRC validation failed * Clear the payload to avoid leakage of data to upper layers */ memset(payload_ptr, 0, count); } #endif return ret; } /** * pm_ipi_send_sync() - Sends IPI request to the remote processor. * @proc: Pointer to the processor who is initiating request. * @payload: API id and call arguments to be written in IPI buffer. * @value: Used to return value from IPI buffer element (optional). * @count: Number of values to return in @value. * * Send an IPI request to the power controller and wait for it to be handled. * * Return: Returns status, either success or error+reason and, optionally, * @value. * */ enum pm_ret_status pm_ipi_send_sync(const struct pm_proc *proc, uint32_t payload[PAYLOAD_ARG_CNT], uint32_t *value, size_t count) { enum pm_ret_status ret; pm_ipi_lock_get(); ret = pm_ipi_send_common(proc, payload, IPI_BLOCKING); if (ret != PM_RET_SUCCESS) { goto unlock; } ret = ERROR_CODE_MASK & (pm_ipi_buff_read(proc, value, count)); unlock: pm_ipi_lock_release(); return ret; } void pm_ipi_irq_enable(const struct pm_proc *proc) { ipi_mb_enable_irq(proc->ipi->local_ipi_id, proc->ipi->remote_ipi_id); } void pm_ipi_irq_clear(const struct pm_proc *proc) { ipi_mb_ack(proc->ipi->local_ipi_id, proc->ipi->remote_ipi_id); } uint32_t pm_ipi_irq_status(const struct pm_proc *proc) { int32_t ret; ret = ipi_mb_enquire_status(proc->ipi->local_ipi_id, proc->ipi->remote_ipi_id); if (ret & IPI_MB_STATUS_RECV_PENDING) { return 1; } else { return 0; } } #if IPI_CRC_CHECK uint32_t calculate_crc(uint32_t payload[PAYLOAD_ARG_CNT], uint32_t bufsize) { uint32_t crcinit = CRC_INIT_VALUE; uint32_t order = CRC_ORDER; uint32_t polynom = CRC_POLYNOM; uint32_t i, j, c, bit, datain, crcmask, crchighbit; uint32_t crc = crcinit; crcmask = ((uint32_t)((1U << (order - 1U)) - 1U) << 1U) | 1U; crchighbit = (uint32_t)(1U << (order - 1U)); for (i = 0U; i < bufsize; i++) { datain = mmio_read_8((unsigned long)payload + i); c = datain; j = 0x80U; while (j != 0U) { bit = crc & crchighbit; crc <<= 1U; if (0U != (c & j)) bit ^= crchighbit; if (bit != 0U) crc ^= polynom; j >>= 1U; } crc &= crcmask; } return crc; } #endif