/* * This file is part of the coreboot project. * * Copyright (C) 2009 coresystems GmbH * Copyright (C) 2013 Sage Electronic Engineering, LLC. * * This program is free software; you can redistribute it and/or modify * it under the terms of the GNU General Public License as published by * the Free Software Foundation; version 2 of the License. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. */ #include #include #include /* Read the current PIC IRQ mask */ u16 pic_read_irq_mask(void) { u16 mask; int i; mask = inb(MASTER_PIC_OCW1) | (inb(SLAVE_PIC_OCW1) << 8); printk(BIOS_DEBUG, "8259 PIC: OCW1 IRQ Mask: 0x%x\n", mask); printk(BIOS_SPEW, "\tEnabled IRQs (0 = Unmasked, 1 = Masked off):\n" "\t\tMaster\t\tSlave\n"); for (i = 0; i <= 7; i++) { printk(BIOS_SPEW, "\t\tIRQ%X: %x\t\tIRQ%X: %x\n", i, (mask >> i) & 1, i + 8, (mask >> (i + 8)) & 1); } return mask; } /* * Write an IRQ mask to the PIC: * IRQA is bit 0xA in the 16 bit bitmask (OCW1) */ void pic_write_irq_mask(u16 mask) { outb(mask, MASTER_PIC_OCW1); outb(mask >> 8, SLAVE_PIC_OCW1); } /* * The PIC IRQs default to masked off * Allow specific IRQs to be enabled (1) * or disabled by (0) the user */ void pic_irq_enable(u8 int_num, u8 mask) { pic_write_irq_mask(pic_read_irq_mask() & ~(mask << int_num)); pic_read_irq_mask(); } void setup_i8259(void) { /* A write to ICW1 starts the Interrupt Controller Initialization * Sequence. This implicitly causes the following to happen: * - Interrupt Mask register is cleared * - Priority 7 is assigned to IRQ7 input * - Slave mode address is set to 7 * - Special mask mode is cleared * * We send the initialization sequence to both the master and * slave i8259 controller. */ outb(ICW_SELECT|IC4, MASTER_PIC_ICW1); outb(ICW_SELECT|IC4, SLAVE_PIC_ICW1); /* Now the interrupt controller expects us to write to ICW2. */ outb(INT_VECTOR_MASTER | IRQ0, MASTER_PIC_ICW2); outb(INT_VECTOR_SLAVE | IRQ8, SLAVE_PIC_ICW2); /* Now the interrupt controller expects us to write to ICW3. * * The normal scenario is to set up cascading on IRQ2 on the master * i8259 and assign the slave ID 2 to the slave i8259. */ outb(CASCADED_PIC, MASTER_PIC_ICW3); outb(SLAVE_ID, SLAVE_PIC_ICW3); /* Now the interrupt controller expects us to write to ICW4. * * We switch both i8259 to microprocessor mode because they're * operating as part of an x86 architecture based chipset */ outb(MICROPROCESSOR_MODE, MASTER_PIC_ICW2); outb(MICROPROCESSOR_MODE, SLAVE_PIC_ICW2); /* Now clear the interrupts through OCW1. * First we mask off all interrupts on the slave interrupt controller * then we mask off all interrupts but interrupt 2 on the master * controller. This way the cascading stays alive. */ outb(ALL_IRQS, SLAVE_PIC_OCW1); outb(ALL_IRQS & ~IRQ2, MASTER_PIC_OCW1); } /** * @brief Configure IRQ triggering in the i8259 compatible Interrupt Controller. * * Switch a certain interrupt to be level / edge triggered. * * @param int_num legacy interrupt number (3-7, 9-15) * @param is_level_triggered 1 for level triggered interrupt, 0 for edge * triggered interrupt */ void i8259_configure_irq_trigger(int int_num, int is_level_triggered) { u16 int_bits = inb(ELCR1) | (((u16)inb(ELCR2)) << 8); if (is_level_triggered) int_bits |= (1 << int_num); else int_bits &= ~(1 << int_num); /* Write new values */ outb((u8)(int_bits & 0xff), ELCR1); outb((u8)(int_bits >> 8), ELCR2); #ifdef PARANOID_IRQ_TRIGGERS /* Try reading back the new values. This seems like an error * but it is not. */ if (inb(ELCR1) != (int_bits & 0xff)) { printk(BIOS_ERR, "%s: lower order bits are wrong: want 0x%x, got 0x%x\n", __func__, (int_bits & 0xff), inb(ELCR1)); } if (inb(ELCR2) != (int_bits >> 8)) { printk(BIOS_ERR, "%s: higher order bits are wrong: want 0x%x, got 0x%x\n", __func__, (int_bits>>8), inb(ELCR2)); } #endif }