/**************************************************************************//** * @file irq_ctrl_gic.c * @brief Interrupt controller handling implementation for GIC * @version V1.0.1 * @date 9. April 2018 ******************************************************************************/ /* * Copyright (c) 2017 ARM Limited. All rights reserved. * * SPDX-License-Identifier: Apache-2.0 * * Licensed under the Apache License, Version 2.0 (the License); you may * not use this file except in compliance with the License. * You may obtain a copy of the License at * * www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an AS IS BASIS, WITHOUT * WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. */ #include #include "RTE_Components.h" #include CMSIS_device_header #include "irq_ctrl.h" #if defined(__GIC_PRESENT) && (__GIC_PRESENT == 1U) /// Number of implemented interrupt lines #ifndef IRQ_GIC_LINE_COUNT #define IRQ_GIC_LINE_COUNT (1020U) #endif extern IRQHandler_t IRQTable[IRQ_GIC_LINE_COUNT]; static uint32_t IRQ_ID0; /// Initialize interrupt controller. __WEAK int32_t IRQ_Initialize (void) { uint32_t i; for (i = 0U; i < IRQ_GIC_LINE_COUNT; i++) { IRQTable[i] = (IRQHandler_t)NULL; } GIC_Enable(); return (0); } /// Register interrupt handler. __WEAK int32_t IRQ_SetHandler (IRQn_ID_t irqn, IRQHandler_t handler) { int32_t status; if ((irqn >= 0) && (irqn < (IRQn_ID_t)IRQ_GIC_LINE_COUNT)) { IRQTable[irqn] = handler; status = 0; } else { status = -1; } return (status); } /// Get the registered interrupt handler. __WEAK IRQHandler_t IRQ_GetHandler (IRQn_ID_t irqn) { IRQHandler_t h; // Ignore CPUID field (software generated interrupts) irqn &= 0x3FFU; if ((irqn >= 0) && (irqn < (IRQn_ID_t)IRQ_GIC_LINE_COUNT)) { h = IRQTable[irqn]; } else { h = (IRQHandler_t)0; } return (h); } /// Enable interrupt. __WEAK int32_t IRQ_Enable (IRQn_ID_t irqn) { int32_t status; if ((irqn >= 0) && (irqn < (IRQn_ID_t)IRQ_GIC_LINE_COUNT)) { GIC_EnableIRQ ((IRQn_Type)irqn); status = 0; } else { status = -1; } return (status); } /// Disable interrupt. __WEAK int32_t IRQ_Disable (IRQn_ID_t irqn) { int32_t status; if ((irqn >= 0) && (irqn < (IRQn_ID_t)IRQ_GIC_LINE_COUNT)) { GIC_DisableIRQ ((IRQn_Type)irqn); status = 0; } else { status = -1; } return (status); } /// Get interrupt enable state. __WEAK uint32_t IRQ_GetEnableState (IRQn_ID_t irqn) { uint32_t enable; if ((irqn >= 0) && (irqn < (IRQn_ID_t)IRQ_GIC_LINE_COUNT)) { enable = GIC_GetEnableIRQ((IRQn_Type)irqn); } else { enable = 0U; } return (enable); } /// Configure interrupt request mode. __WEAK int32_t IRQ_SetMode (IRQn_ID_t irqn, uint32_t mode) { uint32_t val; uint8_t cfg; uint8_t secure; uint8_t cpu; int32_t status = 0; if ((irqn >= 0) && (irqn < (IRQn_ID_t)IRQ_GIC_LINE_COUNT)) { // Check triggering mode val = (mode & IRQ_MODE_TRIG_Msk); if (val == IRQ_MODE_TRIG_LEVEL) { cfg = 0x00U; } else if (val == IRQ_MODE_TRIG_EDGE) { cfg = 0x02U; } else { cfg = 0x00U; status = -1; } // Check interrupt type val = mode & IRQ_MODE_TYPE_Msk; if (val != IRQ_MODE_TYPE_IRQ) { status = -1; } // Check interrupt domain val = mode & IRQ_MODE_DOMAIN_Msk; if (val == IRQ_MODE_DOMAIN_NONSECURE) { secure = 0U; } else { // Check security extensions support val = GIC_DistributorInfo() & (1UL << 10U); if (val != 0U) { // Security extensions are supported secure = 1U; } else { secure = 0U; status = -1; } } // Check interrupt CPU targets val = mode & IRQ_MODE_CPU_Msk; if (val == IRQ_MODE_CPU_ALL) { cpu = 0xFFU; } else { cpu = val >> IRQ_MODE_CPU_Pos; } // Apply configuration if no mode error if (status == 0) { GIC_SetConfiguration((IRQn_Type)irqn, cfg); GIC_SetTarget ((IRQn_Type)irqn, cpu); if (secure != 0U) { GIC_SetGroup ((IRQn_Type)irqn, secure); } } } return (status); } /// Get interrupt mode configuration. __WEAK uint32_t IRQ_GetMode (IRQn_ID_t irqn) { uint32_t mode; uint32_t val; if ((irqn >= 0) && (irqn < (IRQn_ID_t)IRQ_GIC_LINE_COUNT)) { mode = IRQ_MODE_TYPE_IRQ; // Get trigger mode val = GIC_GetConfiguration((IRQn_Type)irqn); if ((val & 2U) != 0U) { // Corresponding interrupt is edge triggered mode |= IRQ_MODE_TRIG_EDGE; } else { // Corresponding interrupt is level triggered mode |= IRQ_MODE_TRIG_LEVEL; } // Get interrupt CPU targets mode |= GIC_GetTarget ((IRQn_Type)irqn) << IRQ_MODE_CPU_Pos; } else { mode = IRQ_MODE_ERROR; } return (mode); } /// Get ID number of current interrupt request (IRQ). __WEAK IRQn_ID_t IRQ_GetActiveIRQ (void) { IRQn_ID_t irqn; uint32_t prio; /* Dummy read to avoid GIC 390 errata 801120 */ GIC_GetHighPendingIRQ(); irqn = GIC_AcknowledgePending(); __DSB(); /* Workaround GIC 390 errata 733075 (GIC-390_Errata_Notice_v6.pdf, 09-Jul-2014) */ /* The following workaround code is for a single-core system. It would be */ /* different in a multi-core system. */ /* If the ID is 0 or 0x3FE or 0x3FF, then the GIC CPU interface may be locked-up */ /* so unlock it, otherwise service the interrupt as normal. */ /* Special IDs 1020=0x3FC and 1021=0x3FD are reserved values in GICv1 and GICv2 */ /* so will not occur here. */ if ((irqn == 0) || (irqn >= 0x3FE)) { /* Unlock the CPU interface with a dummy write to Interrupt Priority Register */ prio = GIC_GetPriority((IRQn_Type)0); GIC_SetPriority ((IRQn_Type)0, prio); __DSB(); if ((irqn == 0U) && ((GIC_GetIRQStatus ((IRQn_Type)irqn) & 1U) != 0U) && (IRQ_ID0 == 0U)) { /* If the ID is 0, is active and has not been seen before */ IRQ_ID0 = 1U; } /* End of Workaround GIC 390 errata 733075 */ } return (irqn); } /// Get ID number of current fast interrupt request (FIQ). __WEAK IRQn_ID_t IRQ_GetActiveFIQ (void) { return ((IRQn_ID_t)-1); } /// Signal end of interrupt processing. __WEAK int32_t IRQ_EndOfInterrupt (IRQn_ID_t irqn) { int32_t status; IRQn_Type irq = (IRQn_Type)irqn; irqn &= 0x3FFU; if ((irqn >= 0) && (irqn < (IRQn_ID_t)IRQ_GIC_LINE_COUNT)) { GIC_EndInterrupt (irq); if (irqn == 0) { IRQ_ID0 = 0U; } status = 0; } else { status = -1; } return (status); } /// Set interrupt pending flag. __WEAK int32_t IRQ_SetPending (IRQn_ID_t irqn) { int32_t status; if ((irqn >= 0) && (irqn < (IRQn_ID_t)IRQ_GIC_LINE_COUNT)) { GIC_SetPendingIRQ ((IRQn_Type)irqn); status = 0; } else { status = -1; } return (status); } /// Get interrupt pending flag. __WEAK uint32_t IRQ_GetPending (IRQn_ID_t irqn) { uint32_t pending; if ((irqn >= 16) && (irqn < (IRQn_ID_t)IRQ_GIC_LINE_COUNT)) { pending = GIC_GetPendingIRQ ((IRQn_Type)irqn); } else { pending = 0U; } return (pending & 1U); } /// Clear interrupt pending flag. __WEAK int32_t IRQ_ClearPending (IRQn_ID_t irqn) { int32_t status; if ((irqn >= 16) && (irqn < (IRQn_ID_t)IRQ_GIC_LINE_COUNT)) { GIC_ClearPendingIRQ ((IRQn_Type)irqn); status = 0; } else { status = -1; } return (status); } /// Set interrupt priority value. __WEAK int32_t IRQ_SetPriority (IRQn_ID_t irqn, uint32_t priority) { int32_t status; if ((irqn >= 0) && (irqn < (IRQn_ID_t)IRQ_GIC_LINE_COUNT)) { GIC_SetPriority ((IRQn_Type)irqn, priority); status = 0; } else { status = -1; } return (status); } /// Get interrupt priority. __WEAK uint32_t IRQ_GetPriority (IRQn_ID_t irqn) { uint32_t priority; if ((irqn >= 0) && (irqn < (IRQn_ID_t)IRQ_GIC_LINE_COUNT)) { priority = GIC_GetPriority ((IRQn_Type)irqn); } else { priority = IRQ_PRIORITY_ERROR; } return (priority); } /// Set priority masking threshold. __WEAK int32_t IRQ_SetPriorityMask (uint32_t priority) { GIC_SetInterfacePriorityMask (priority); return (0); } /// Get priority masking threshold __WEAK uint32_t IRQ_GetPriorityMask (void) { return GIC_GetInterfacePriorityMask(); } /// Set priority grouping field split point __WEAK int32_t IRQ_SetPriorityGroupBits (uint32_t bits) { int32_t status; if (bits == IRQ_PRIORITY_Msk) { bits = 7U; } if (bits < 8U) { GIC_SetBinaryPoint (7U - bits); status = 0; } else { status = -1; } return (status); } /// Get priority grouping field split point __WEAK uint32_t IRQ_GetPriorityGroupBits (void) { uint32_t bp; bp = GIC_GetBinaryPoint() & 0x07U; return (7U - bp); } #endif