/* * Copyright (c) 2013-2022, Arm Limited and Contributors. All rights reserved. * Copyright (c) 2023, Advanced Micro Devices, Inc. All rights reserved. * * SPDX-License-Identifier: BSD-3-Clause */ /* * Top-level SMC handler for ZynqMP power management calls and * IPI setup functions for communication with PMU. */ #include #include #include #include #include #include #include #include #include "pm_client.h" #include "pm_ipi.h" #include "zynqmp_pm_api_sys.h" #include "zynqmp_pm_defs.h" /* pm_up = !0 - UP, pm_up = 0 - DOWN */ static int32_t pm_up, ipi_irq_flag; #if ZYNQMP_WDT_RESTART static spinlock_t inc_lock; static int active_cores = 0; #endif /** * typedef pm_ctx_t - Structure which contains data for power management. * @api_version: version of PM API, must match with one on PMU side. * @payload: payload array used to store received. * data from ipi buffer registers. * */ typedef struct { uint32_t api_version; uint32_t payload[PAYLOAD_ARG_CNT]; } pm_ctx_t; static pm_ctx_t pm_ctx; #if ZYNQMP_WDT_RESTART /** * trigger_wdt_restart() - Trigger warm restart event to APU cores. * * This function triggers SGI for all active APU CPUs. SGI handler then * power down CPU and call system reset. * */ static void trigger_wdt_restart(void) { uint32_t core_count = 0; uint32_t core_status[3]; uint32_t target_cpu_list = 0; int i; for (i = 0; i < 4; i++) { pm_get_node_status(NODE_APU_0 + i, core_status); if (core_status[0] == 1) { core_count++; target_cpu_list |= (1 << i); } } spin_lock(&inc_lock); active_cores = core_count; spin_unlock(&inc_lock); INFO("Active Cores: %d\n", active_cores); for (i = PLATFORM_CORE_COUNT - 1; i >= 0; i--) { if (target_cpu_list & (1 << i)) { /* trigger SGI to active cores */ plat_ic_raise_el3_sgi(ARM_IRQ_SEC_SGI_7, i); } } } /** * ttc_fiq_handler() - TTC Handler for timer event. * @id: number of the highest priority pending interrupt of the type * that this handler was registered for. * @flags: security state, bit[0]. * @handle: pointer to 'cpu_context' structure of the current CPU for the * security state specified in the 'flags' parameter. * @cookie: unused. * * Function registered as INTR_TYPE_EL3 interrupt handler. * * When WDT event is received in PMU, PMU needs to notify master to do cleanup * if required. PMU sets up timer and starts timer to overflow in zero time upon * WDT event. TF-A handles this timer event and takes necessary action required * for warm restart. * * In presence of non-secure software layers (EL1/2) sets the interrupt * at registered entrance in GIC and informs that PMU responded or demands * action. * * Return: 0 on success. * */ static uint64_t ttc_fiq_handler(uint32_t id, uint32_t flags, void *handle, void *cookie) { INFO("BL31: Got TTC FIQ\n"); plat_ic_end_of_interrupt(id); /* Clear TTC interrupt by reading interrupt register */ mmio_read_32(TTC3_INTR_REGISTER_1); /* Disable the timer interrupts */ mmio_write_32(TTC3_INTR_ENABLE_1, 0); trigger_wdt_restart(); return 0; } /** * zynqmp_sgi7_irq() - Handler for SGI7 IRQ. * @id: number of the highest priority pending interrupt of the type * that this handler was registered for. * @flags: security state, bit[0]. * @handle: pointer to 'cpu_context' structure of the current CPU for the * security state specified in the 'flags' parameter. * @cookie: unused. * * Function registered as INTR_TYPE_EL3 interrupt handler * * On receiving WDT event from PMU, TF-A generates SGI7 to all running CPUs. * In response to SGI7 interrupt, each CPUs do clean up if required and last * running CPU calls system restart. * * Return: This function does not return a value and it enters into wfi. */ static uint64_t __unused __dead2 zynqmp_sgi7_irq(uint32_t id, uint32_t flags, void *handle, void *cookie) { int i; uint32_t value; /* enter wfi and stay there */ INFO("Entering wfi\n"); spin_lock(&inc_lock); active_cores--; for (i = 0; i < 4; i++) { mmio_write_32(BASE_GICD_BASE + GICD_CPENDSGIR + 4 * i, 0xffffffff); } dsb(); spin_unlock(&inc_lock); if (active_cores == 0) { pm_mmio_read(PMU_GLOBAL_GEN_STORAGE4, &value); value = (value & RESTART_SCOPE_MASK) >> RESTART_SCOPE_SHIFT; pm_system_shutdown(PMF_SHUTDOWN_TYPE_RESET, value); } /* enter wfi and stay there */ while (1) wfi(); } /** * pm_wdt_restart_setup() - Setup warm restart interrupts. * * Return: Returns status, 0 on success or error+reason. * * This function sets up handler for SGI7 and TTC interrupts * used for warm restart. */ static int pm_wdt_restart_setup(void) { int ret; /* register IRQ handler for SGI7 */ ret = request_intr_type_el3(ARM_IRQ_SEC_SGI_7, zynqmp_sgi7_irq); if (ret) { WARN("BL31: registering SGI7 interrupt failed\n"); goto err; } ret = request_intr_type_el3(IRQ_TTC3_1, ttc_fiq_handler); if (ret) WARN("BL31: registering TTC3 interrupt failed\n"); err: return ret; } #endif /** * pm_setup() - PM service setup. * * Return: On success, the initialization function must return 0. * Any other return value will cause the framework to ignore * the service. * * Initialization functions for ZynqMP power management for * communicaton with PMU. * * Called from sip_svc_setup initialization function with the * rt_svc_init signature. * */ int32_t pm_setup(void) { enum pm_ret_status err; pm_ipi_init(primary_proc); err = pm_get_api_version(&pm_ctx.api_version); if (err != PM_RET_SUCCESS) { ERROR("BL31: Failed to read Platform Management API version. " "Return: %d\n", err); return -EINVAL; } if (pm_ctx.api_version < PM_VERSION) { ERROR("BL31: Platform Management API version error. Expected: " "v%d.%d - Found: v%d.%d\n", PM_VERSION_MAJOR, PM_VERSION_MINOR, pm_ctx.api_version >> 16, pm_ctx.api_version & 0xFFFFU); return -EINVAL; } int32_t status = 0, ret = 0; #if ZYNQMP_WDT_RESTART status = pm_wdt_restart_setup(); if (status) WARN("BL31: warm-restart setup failed\n"); #endif if (status >= 0) { INFO("BL31: PM Service Init Complete: API v%d.%d\n", PM_VERSION_MAJOR, PM_VERSION_MINOR); ret = 0; } else { INFO("BL31: PM Service Init Failed, Error Code %d!\n", status); ret = status; } pm_up = !status; return ret; } /** * pm_smc_handler() - SMC handler for PM-API calls coming from EL1/EL2. * @smc_fid: Function Identifier. * @x1: Arguments. * @x2: Arguments. * @x3: Arguments. * @x4: Arguments. * @cookie: Unused. * @handle: Pointer to caller's context structure. * @flags: SECURE_FLAG or NON_SECURE_FLAG. * * Determines that smc_fid is valid and supported PM SMC Function ID from the * list of pm_api_ids, otherwise completes the request with * the unknown SMC Function ID. * * The SMC calls for PM service are forwarded from SIP Service SMC handler * function with rt_svc_handle signature. * * Return: Unused. * */ uint64_t pm_smc_handler(uint32_t smc_fid, uint64_t x1, uint64_t x2, uint64_t x3, uint64_t x4, const void *cookie, void *handle, uint64_t flags) { enum pm_ret_status ret; uint32_t payload[PAYLOAD_ARG_CNT]; uint32_t pm_arg[5]; uint32_t result[PAYLOAD_ARG_CNT] = {0}; uint32_t api_id; /* Handle case where PM wasn't initialized properly */ if (pm_up == 0) SMC_RET1(handle, SMC_UNK); pm_arg[0] = (uint32_t)x1; pm_arg[1] = (uint32_t)(x1 >> 32); pm_arg[2] = (uint32_t)x2; pm_arg[3] = (uint32_t)(x2 >> 32); pm_arg[4] = (uint32_t)x3; api_id = smc_fid & FUNCID_NUM_MASK; switch (api_id) { /* PM API Functions */ case PM_SELF_SUSPEND: ret = pm_self_suspend(pm_arg[0], pm_arg[1], pm_arg[2], pm_arg[3]); SMC_RET1(handle, (uint64_t)ret); case PM_REQ_SUSPEND: ret = pm_req_suspend(pm_arg[0], pm_arg[1], pm_arg[2], pm_arg[3]); SMC_RET1(handle, (uint64_t)ret); case PM_REQ_WAKEUP: { /* Use address flag is encoded in the 1st bit of the low-word */ uint32_t set_addr = pm_arg[1] & 0x1U; uint64_t address = (uint64_t)pm_arg[2] << 32U; address |= pm_arg[1] & (~0x1U); ret = pm_req_wakeup(pm_arg[0], set_addr, address, pm_arg[3]); SMC_RET1(handle, (uint64_t)ret); } case PM_FORCE_POWERDOWN: ret = pm_force_powerdown(pm_arg[0], pm_arg[1]); SMC_RET1(handle, (uint64_t)ret); case PM_ABORT_SUSPEND: ret = pm_abort_suspend(pm_arg[0]); SMC_RET1(handle, (uint64_t)ret); case PM_SET_WAKEUP_SOURCE: ret = pm_set_wakeup_source(pm_arg[0], pm_arg[1], pm_arg[2]); SMC_RET1(handle, (uint64_t)ret); case PM_SYSTEM_SHUTDOWN: ret = pm_system_shutdown(pm_arg[0], pm_arg[1]); SMC_RET1(handle, (uint64_t)ret); case PM_REQ_NODE: ret = pm_req_node(pm_arg[0], pm_arg[1], pm_arg[2], pm_arg[3]); SMC_RET1(handle, (uint64_t)ret); case PM_SET_REQUIREMENT: ret = pm_set_requirement(pm_arg[0], pm_arg[1], pm_arg[2], pm_arg[3]); SMC_RET1(handle, (uint64_t)ret); case PM_GET_API_VERSION: if (ipi_irq_flag == 0U) { /* * Enable IPI IRQ * assume the rich OS is OK to handle callback IRQs now. * Even if we were wrong, it would not enable the IRQ in * the GIC. */ pm_ipi_irq_enable(primary_proc); ipi_irq_flag = 1U; } SMC_RET1(handle, (uint64_t)PM_RET_SUCCESS | ((uint64_t)pm_ctx.api_version << 32)); case PM_FPGA_LOAD: ret = pm_fpga_load(pm_arg[0], pm_arg[1], pm_arg[2], pm_arg[3]); SMC_RET1(handle, (uint64_t)ret); case PM_FPGA_GET_STATUS: { uint32_t value = 0U; ret = pm_fpga_get_status(&value); SMC_RET1(handle, (uint64_t)ret | ((uint64_t)value) << 32); } case PM_SECURE_RSA_AES: ret = pm_secure_rsaaes(pm_arg[0], pm_arg[1], pm_arg[2], pm_arg[3]); SMC_RET1(handle, (uint64_t)ret); case PM_GET_CALLBACK_DATA: ret = pm_get_callbackdata(result, ARRAY_SIZE(result)); if (ret != PM_RET_SUCCESS) { result[0] = ret; } SMC_RET2(handle, (uint64_t)result[0] | ((uint64_t)result[1] << 32), (uint64_t)result[2] | ((uint64_t)result[3] << 32)); case PM_IOCTL: { uint32_t value = 0U; ret = pm_ioctl(pm_arg[0], pm_arg[1], pm_arg[2], pm_arg[3], &value); SMC_RET1(handle, (uint64_t)ret | ((uint64_t)value) << 32); } case PM_QUERY_DATA: { uint32_t data[4] = { 0 }; pm_query_data(pm_arg[0], pm_arg[1], pm_arg[2], pm_arg[3], data); SMC_RET2(handle, (uint64_t)data[0] | ((uint64_t)data[1] << 32), (uint64_t)data[2] | ((uint64_t)data[3] << 32)); } case PM_CLOCK_ENABLE: ret = pm_clock_enable(pm_arg[0]); SMC_RET1(handle, (uint64_t)ret); case PM_CLOCK_DISABLE: ret = pm_clock_disable(pm_arg[0]); SMC_RET1(handle, (uint64_t)ret); case PM_CLOCK_GETSTATE: { uint32_t value = 0U; ret = pm_clock_getstate(pm_arg[0], &value); SMC_RET1(handle, (uint64_t)ret | ((uint64_t)value) << 32); } case PM_CLOCK_SETDIVIDER: ret = pm_clock_setdivider(pm_arg[0], pm_arg[1]); SMC_RET1(handle, (uint64_t)ret); case PM_CLOCK_GETDIVIDER: { uint32_t value = 0U; ret = pm_clock_getdivider(pm_arg[0], &value); SMC_RET1(handle, (uint64_t)ret | ((uint64_t)value) << 32); } case PM_CLOCK_SETPARENT: ret = pm_clock_setparent(pm_arg[0], pm_arg[1]); SMC_RET1(handle, (uint64_t)ret); case PM_CLOCK_GETPARENT: { uint32_t value = 0U; ret = pm_clock_getparent(pm_arg[0], &value); SMC_RET1(handle, (uint64_t)ret | ((uint64_t)value) << 32U); } case PM_GET_TRUSTZONE_VERSION: SMC_RET1(handle, (uint64_t)PM_RET_SUCCESS | ((uint64_t)ZYNQMP_TZ_VERSION << 32U)); case PM_SET_SUSPEND_MODE: ret = pm_set_suspend_mode(pm_arg[0]); SMC_RET1(handle, (uint64_t)ret); case PM_SECURE_SHA: ret = pm_sha_hash(pm_arg[0], pm_arg[1], pm_arg[2], pm_arg[3]); SMC_RET1(handle, (uint64_t)ret); case PM_SECURE_RSA: ret = pm_rsa_core(pm_arg[0], pm_arg[1], pm_arg[2], pm_arg[3]); SMC_RET1(handle, (uint64_t)ret); case PM_SECURE_IMAGE: { ret = pm_secure_image(pm_arg[0], pm_arg[1], pm_arg[2], pm_arg[3], &result[0]); SMC_RET2(handle, (uint64_t)ret | ((uint64_t)result[0] << 32U), result[1]); } case PM_FPGA_READ: { uint32_t value = 0U; ret = pm_fpga_read(pm_arg[0], pm_arg[1], pm_arg[2], pm_arg[3], &value); SMC_RET1(handle, (uint64_t)ret | ((uint64_t)value) << 32U); } case PM_SECURE_AES: { uint32_t value = 0U; ret = pm_aes_engine(pm_arg[0], pm_arg[1], &value); SMC_RET1(handle, (uint64_t)ret | ((uint64_t)value) << 32U); } case PM_PLL_SET_PARAMETER: ret = pm_pll_set_parameter(pm_arg[0], pm_arg[1], pm_arg[2]); SMC_RET1(handle, (uint64_t)ret); case PM_PLL_GET_PARAMETER: { uint32_t value = 0U; ret = pm_pll_get_parameter(pm_arg[0], pm_arg[1], &value); SMC_RET1(handle, (uint64_t)ret | ((uint64_t)value << 32U)); } case PM_PLL_SET_MODE: ret = pm_pll_set_mode(pm_arg[0], pm_arg[1]); SMC_RET1(handle, (uint64_t)ret); case PM_PLL_GET_MODE: { uint32_t mode = 0U; ret = pm_pll_get_mode(pm_arg[0], &mode); SMC_RET1(handle, (uint64_t)ret | ((uint64_t)mode << 32U)); } case PM_REGISTER_ACCESS: { uint32_t value = 0U; ret = pm_register_access(pm_arg[0], pm_arg[1], pm_arg[2], pm_arg[3], &value); SMC_RET1(handle, (uint64_t)ret | ((uint64_t)value) << 32U); } case PM_EFUSE_ACCESS: { uint32_t value = 0U; #if defined(ZYNQMP_SECURE_EFUSES) if (is_caller_non_secure(flags)) { SMC_RET1(handle, (((uint64_t)PM_RET_ERROR_NOT_ENABLED) << 32U) | (uint64_t)PM_RET_ERROR_ACCESS); } #endif ret = pm_efuse_access(pm_arg[0], pm_arg[1], &value); SMC_RET1(handle, (uint64_t)ret | ((uint64_t)value) << 32U); } case PM_FPGA_GET_VERSION: case PM_FPGA_GET_FEATURE_LIST: { uint32_t ret_payload[PAYLOAD_ARG_CNT]; PM_PACK_PAYLOAD5(payload, smc_fid & FUNCID_NUM_MASK, pm_arg[0], pm_arg[1], pm_arg[2], pm_arg[3]); ret = pm_ipi_send_sync(primary_proc, payload, ret_payload, 3U); SMC_RET2(handle, (uint64_t)ret | (uint64_t)ret_payload[0] << 32U, (uint64_t)ret_payload[1] | (uint64_t)ret_payload[2] << 32U); } case PM_FEATURE_CHECK: { uint32_t version = 0; uint32_t bit_mask[2] = {0}; ret = pm_feature_check(pm_arg[0], &version, bit_mask, ARRAY_SIZE(bit_mask)); SMC_RET2(handle, (uint64_t)ret | ((uint64_t)version << 32U), (uint64_t)bit_mask[0] | ((uint64_t)bit_mask[1] << 32U)); } default: /* Send request to the PMU */ PM_PACK_PAYLOAD6(payload, api_id, pm_arg[0], pm_arg[1], pm_arg[2], pm_arg[3], pm_arg[4]); ret = pm_ipi_send_sync(primary_proc, payload, result, PAYLOAD_ARG_CNT); SMC_RET2(handle, (uint64_t)ret | ((uint64_t)result[0] << 32U), (uint64_t)result[1] | ((uint64_t)result[2] << 32U)); } }