/* * Copyright (c) 2015-2017, ARM Limited and Contributors. All rights reserved. * * SPDX-License-Identifier: BSD-3-Clause */ #include #include #include #include /* * The following platform GIC functions are weakly defined. They * provide typical implementations that may be re-used by multiple * platforms but may also be overridden by a platform if required. */ #pragma weak plat_ic_get_pending_interrupt_id #pragma weak plat_ic_get_pending_interrupt_type #pragma weak plat_ic_acknowledge_interrupt #pragma weak plat_ic_get_interrupt_type #pragma weak plat_ic_end_of_interrupt #pragma weak plat_interrupt_type_to_line #pragma weak plat_ic_get_running_priority #pragma weak plat_ic_is_spi #pragma weak plat_ic_is_ppi #pragma weak plat_ic_is_sgi #pragma weak plat_ic_get_interrupt_active #pragma weak plat_ic_enable_interrupt #pragma weak plat_ic_disable_interrupt #pragma weak plat_ic_set_interrupt_priority #pragma weak plat_ic_set_interrupt_type /* * This function returns the highest priority pending interrupt at * the Interrupt controller */ uint32_t plat_ic_get_pending_interrupt_id(void) { unsigned int id; id = gicv2_get_pending_interrupt_id(); if (id == GIC_SPURIOUS_INTERRUPT) return INTR_ID_UNAVAILABLE; return id; } /* * This function returns the type of the highest priority pending interrupt * at the Interrupt controller. In the case of GICv2, the Highest Priority * Pending interrupt register (`GICC_HPPIR`) is read to determine the id of * the pending interrupt. The type of interrupt depends upon the id value * as follows. * 1. id < PENDING_G1_INTID (1022) is reported as a S-EL1 interrupt * 2. id = PENDING_G1_INTID (1022) is reported as a Non-secure interrupt. * 3. id = GIC_SPURIOUS_INTERRUPT (1023) is reported as an invalid interrupt * type. */ uint32_t plat_ic_get_pending_interrupt_type(void) { unsigned int id; id = gicv2_get_pending_interrupt_type(); /* Assume that all secure interrupts are S-EL1 interrupts */ if (id < PENDING_G1_INTID) { #if GICV2_G0_FOR_EL3 return INTR_TYPE_EL3; #else return INTR_TYPE_S_EL1; #endif } if (id == GIC_SPURIOUS_INTERRUPT) return INTR_TYPE_INVAL; return INTR_TYPE_NS; } /* * This function returns the highest priority pending interrupt at * the Interrupt controller and indicates to the Interrupt controller * that the interrupt processing has started. */ uint32_t plat_ic_acknowledge_interrupt(void) { return gicv2_acknowledge_interrupt(); } /* * This function returns the type of the interrupt `id`, depending on how * the interrupt has been configured in the interrupt controller */ uint32_t plat_ic_get_interrupt_type(uint32_t id) { unsigned int type; type = gicv2_get_interrupt_group(id); /* Assume that all secure interrupts are S-EL1 interrupts */ return type == GICV2_INTR_GROUP1 ? INTR_TYPE_NS : #if GICV2_G0_FOR_EL3 INTR_TYPE_EL3; #else INTR_TYPE_S_EL1; #endif } /* * This functions is used to indicate to the interrupt controller that * the processing of the interrupt corresponding to the `id` has * finished. */ void plat_ic_end_of_interrupt(uint32_t id) { gicv2_end_of_interrupt(id); } /* * An ARM processor signals interrupt exceptions through the IRQ and FIQ pins. * The interrupt controller knows which pin/line it uses to signal a type of * interrupt. It lets the interrupt management framework determine * for a type of interrupt and security state, which line should be used in the * SCR_EL3 to control its routing to EL3. The interrupt line is represented * as the bit position of the IRQ or FIQ bit in the SCR_EL3. */ uint32_t plat_interrupt_type_to_line(uint32_t type, uint32_t security_state) { assert(type == INTR_TYPE_S_EL1 || type == INTR_TYPE_EL3 || type == INTR_TYPE_NS); /* Non-secure interrupts are signaled on the IRQ line always */ if (type == INTR_TYPE_NS) return __builtin_ctz(SCR_IRQ_BIT); /* * Secure interrupts are signaled using the IRQ line if the FIQ is * not enabled else they are signaled using the FIQ line. */ return ((gicv2_is_fiq_enabled()) ? __builtin_ctz(SCR_FIQ_BIT) : __builtin_ctz(SCR_IRQ_BIT)); } unsigned int plat_ic_get_running_priority(void) { return gicv2_get_running_priority(); } int plat_ic_is_spi(unsigned int id) { return (id >= MIN_SPI_ID) && (id <= MAX_SPI_ID); } int plat_ic_is_ppi(unsigned int id) { return (id >= MIN_PPI_ID) && (id < MIN_SPI_ID); } int plat_ic_is_sgi(unsigned int id) { return (id >= MIN_SGI_ID) && (id < MIN_PPI_ID); } unsigned int plat_ic_get_interrupt_active(unsigned int id) { return gicv2_get_interrupt_active(id); } void plat_ic_enable_interrupt(unsigned int id) { gicv2_enable_interrupt(id); } void plat_ic_disable_interrupt(unsigned int id) { gicv2_disable_interrupt(id); } void plat_ic_set_interrupt_priority(unsigned int id, unsigned int priority) { gicv2_set_interrupt_priority(id, priority); } int plat_ic_has_interrupt_type(unsigned int type) { switch (type) { #if GICV2_G0_FOR_EL3 case INTR_TYPE_EL3: #else case INTR_TYPE_S_EL1: #endif case INTR_TYPE_NS: return 1; default: return 0; } } void plat_ic_set_interrupt_type(unsigned int id, unsigned int type) { int gicv2_type = 0; /* Map canonical interrupt type to GICv2 type */ switch (type) { #if GICV2_G0_FOR_EL3 case INTR_TYPE_EL3: #else case INTR_TYPE_S_EL1: #endif gicv2_type = GICV2_INTR_GROUP0; break; case INTR_TYPE_NS: gicv2_type = GICV2_INTR_GROUP1; break; default: assert(0); } gicv2_set_interrupt_type(id, gicv2_type); }