/* * Copyright (c) 2015, ARM Limited and Contributors. All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions are met: * * Redistributions of source code must retain the above copyright notice, this * list of conditions and the following disclaimer. * * Redistributions in binary form must reproduce the above copyright notice, * this list of conditions and the following disclaimer in the documentation * and/or other materials provided with the distribution. * * Neither the name of ARM nor the names of its contributors may be used * to endorse or promote products derived from this software without specific * prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" * AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE * ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS BE * LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE * POSSIBILITY OF SUCH DAMAGE. */ #include #include #include #include #include #include "gicv2_private.h" /* * Accessor to read the GIC Distributor ITARGETSR corresponding to the * interrupt `id`, 4 interrupt IDs at a time. */ unsigned int gicd_read_itargetsr(uintptr_t base, unsigned int id) { unsigned n = id >> ITARGETSR_SHIFT; return mmio_read_32(base + GICD_ITARGETSR + (n << 2)); } /* * Accessor to read the GIC Distributor CPENDSGIR corresponding to the * interrupt `id`, 4 interrupt IDs at a time. */ unsigned int gicd_read_cpendsgir(uintptr_t base, unsigned int id) { unsigned n = id >> CPENDSGIR_SHIFT; return mmio_read_32(base + GICD_CPENDSGIR + (n << 2)); } /* * Accessor to read the GIC Distributor SPENDSGIR corresponding to the * interrupt `id`, 4 interrupt IDs at a time. */ unsigned int gicd_read_spendsgir(uintptr_t base, unsigned int id) { unsigned n = id >> SPENDSGIR_SHIFT; return mmio_read_32(base + GICD_SPENDSGIR + (n << 2)); } /* * Accessor to write the GIC Distributor ITARGETSR corresponding to the * interrupt `id`, 4 interrupt IDs at a time. */ void gicd_write_itargetsr(uintptr_t base, unsigned int id, unsigned int val) { unsigned n = id >> ITARGETSR_SHIFT; mmio_write_32(base + GICD_ITARGETSR + (n << 2), val); } /* * Accessor to write the GIC Distributor CPENDSGIR corresponding to the * interrupt `id`, 4 interrupt IDs at a time. */ void gicd_write_cpendsgir(uintptr_t base, unsigned int id, unsigned int val) { unsigned n = id >> CPENDSGIR_SHIFT; mmio_write_32(base + GICD_CPENDSGIR + (n << 2), val); } /* * Accessor to write the GIC Distributor SPENDSGIR corresponding to the * interrupt `id`, 4 interrupt IDs at a time. */ void gicd_write_spendsgir(uintptr_t base, unsigned int id, unsigned int val) { unsigned n = id >> SPENDSGIR_SHIFT; mmio_write_32(base + GICD_SPENDSGIR + (n << 2), val); } /* * Accessor to write the GIC Distributor ITARGETSR corresponding to the * interrupt `id`. */ void gicd_set_itargetsr(uintptr_t base, unsigned int id, unsigned int target) { unsigned byte_off = id & ((1 << ITARGETSR_SHIFT) - 1); unsigned int reg_val = gicd_read_itargetsr(base, id); gicd_write_itargetsr(base, id, reg_val | (target << (byte_off << 3))); } /******************************************************************************* * Get the current CPU bit mask from GICD_ITARGETSR0 ******************************************************************************/ unsigned int gicv2_get_cpuif_id(uintptr_t base) { unsigned int val; val = gicd_read_itargetsr(base, 0); return val & GIC_TARGET_CPU_MASK; } /******************************************************************************* * Helper function to configure the default attributes of SPIs. ******************************************************************************/ void gicv2_spis_configure_defaults(uintptr_t gicd_base) { unsigned int index, num_ints; num_ints = gicd_read_typer(gicd_base); num_ints &= TYPER_IT_LINES_NO_MASK; num_ints = (num_ints + 1) << 5; /* * Treat all SPIs as G1NS by default. The number of interrupts is * calculated as 32 * (IT_LINES + 1). We do 32 at a time. */ for (index = MIN_SPI_ID; index < num_ints; index += 32) gicd_write_igroupr(gicd_base, index, ~0U); /* Setup the default SPI priorities doing four at a time */ for (index = MIN_SPI_ID; index < num_ints; index += 4) gicd_write_ipriorityr(gicd_base, index, GICD_IPRIORITYR_DEF_VAL); /* Treat all SPIs as level triggered by default, 16 at a time */ for (index = MIN_SPI_ID; index < num_ints; index += 16) gicd_write_icfgr(gicd_base, index, 0); } /******************************************************************************* * Helper function to configure secure G0 SPIs. ******************************************************************************/ void gicv2_secure_spis_configure(uintptr_t gicd_base, unsigned int num_ints, const unsigned int *sec_intr_list) { unsigned int index, irq_num; /* If `num_ints` is not 0, ensure that `sec_intr_list` is not NULL */ assert(num_ints ? (uintptr_t)sec_intr_list : 1); for (index = 0; index < num_ints; index++) { irq_num = sec_intr_list[index]; if (irq_num >= MIN_SPI_ID) { /* Configure this interrupt as a secure interrupt */ gicd_clr_igroupr(gicd_base, irq_num); /* Set the priority of this interrupt */ gicd_write_ipriorityr(gicd_base, irq_num, GIC_HIGHEST_SEC_PRIORITY); /* Target the secure interrupts to primary CPU */ gicd_set_itargetsr(gicd_base, irq_num, gicv2_get_cpuif_id(gicd_base)); /* Enable this interrupt */ gicd_set_isenabler(gicd_base, irq_num); } } } /******************************************************************************* * Helper function to configure secure G0 SGIs and PPIs. ******************************************************************************/ void gicv2_secure_ppi_sgi_setup(uintptr_t gicd_base, unsigned int num_ints, const unsigned int *sec_intr_list) { unsigned int index, irq_num, sec_ppi_sgi_mask = 0; /* If `num_ints` is not 0, ensure that `sec_intr_list` is not NULL */ assert(num_ints ? (uintptr_t)sec_intr_list : 1); /* * Disable all SGIs (imp. def.)/PPIs before configuring them. This is a * more scalable approach as it avoids clearing the enable bits in the * GICD_CTLR. */ gicd_write_icenabler(gicd_base, 0, ~0); /* Setup the default PPI/SGI priorities doing four at a time */ for (index = 0; index < MIN_SPI_ID; index += 4) gicd_write_ipriorityr(gicd_base, index, GICD_IPRIORITYR_DEF_VAL); for (index = 0; index < num_ints; index++) { irq_num = sec_intr_list[index]; if (irq_num < MIN_SPI_ID) { /* We have an SGI or a PPI. They are Group0 at reset */ sec_ppi_sgi_mask |= 1U << irq_num; /* Set the priority of this interrupt */ gicd_write_ipriorityr(gicd_base, irq_num, GIC_HIGHEST_SEC_PRIORITY); } } /* * Invert the bitmask to create a mask for non-secure PPIs and * SGIs. Program the GICD_IGROUPR0 with this bit mask. */ gicd_write_igroupr(gicd_base, 0, ~sec_ppi_sgi_mask); /* Enable the Group 0 SGIs and PPIs */ gicd_write_isenabler(gicd_base, 0, sec_ppi_sgi_mask); }