#include "u.h" #include "../port/lib.h" #include "mem.h" #include "dat.h" #include "fns.h" #include "io.h" /* * 8259 Interrupt Controller and compatibles. */ enum { /* I/O ports */ Cntrl1 = 0x20, Cntrl2 = 0xa0, Icw1 = 0, /* Initialisation Command Word 1 */ Icw2 = 1, Icw3 = 1, Icw4 = 1, Ocw1 = 1, /* Operational Control Word 1 */ Ocw2 = 0, Ocw3 = 0, Imr = Ocw1, /* Interrupt Mask Register */ Isr = Ocw3, /* In-Service Register */ Irr = Ocw3, /* Interrupt Request Register */ Elcr1 = 0x4d0, /* Edge/Level Control Register */ Elcr2 = 0x4d1, }; enum { /* Icw1 */ Ic4 = 0x01, /* there will be an Icw4 */ Icw1sel = 0x10, /* Icw/Ocw select */ }; enum { /* Icw3 */ Cascaded = 0x04, /* Cntrl1 - Cascaded Mode Enable */ SlaveIRQ2 = 0x02, /* Cntrl2 - Slave Identification Code */ }; enum { /* Icw4 */ Microprocessor = 0x01, /* 80x86-based system */ }; enum { /* Ocw2 */ Ocw2sel = 0x00, /* Ocw2 select */ Eoi = 0x20, /* Non-spcific EOI command */ }; enum { /* Ocw3 */ Irrread = 0x02, /* Read IRQ register */ Isrread = 0x03, /* Read IS register */ Ocw3sel = 0x08, /* Ocw3 select */ }; static Lock i8259lock; static int i8259mask = ~0; /* mask of disabled interrupts */ static int i8259elcr; /* mask of level interrupts */ int i8259init(int vectorbase) { int elcr; vectorbase &= ~0x07; ilock(&i8259lock); /* * Boilerplate to initialise the pair of 8259 controllers, * see one of the Intel bridge datasheets for details, * e.g. 82371AB (PIIX4). The default settings are 80x86 mode, * edge-sensitive detection, normal EOI, non-buffered and * cascade mode. Cntrl1 is connected as the master and Cntrl2 * as the slave; IRQ2 is used to cascade the two controllers. */ outb(Cntrl1+Icw1, Icw1sel|Ic4); outb(Cntrl1+Icw2, vectorbase); outb(Cntrl1+Icw3, Cascaded); outb(Cntrl1+Icw4, Microprocessor); outb(Cntrl2+Icw1, Icw1sel|Ic4); outb(Cntrl2+Icw2, vectorbase+8); outb(Cntrl2+Icw3, SlaveIRQ2); outb(Cntrl2+Icw4, Microprocessor); /* * Set the interrupt masks, allowing interrupts * to pass from Cntrl2 to Cntrl1 on IRQ2. */ i8259mask &= ~(1<<2); outb(Cntrl2+Imr, (i8259mask>>8) & 0xff); outb(Cntrl1+Imr, i8259mask & 0xff); outb(Cntrl1+Ocw2, Ocw2sel|Eoi); outb(Cntrl2+Ocw2, Ocw2sel|Eoi); /* * Set Ocw3 to return the ISR when read for i8259isr() * (after initialisation status read is set to return the IRR). * Read IRR first to possibly deassert an outstanding * interrupt. */ inb(Cntrl1+Irr); outb(Cntrl1+Ocw3, Ocw3sel|Isrread); inb(Cntrl2+Irr); outb(Cntrl2+Ocw3, Ocw3sel|Isrread); /* * Check for Edge/Level Control register. * This check may not work for all chipsets. * First try a non-intrusive test - the bits for * IRQs 13, 8, 2, 1 and 0 must be edge (0). If * that's OK try a R/W test. */ elcr = (inb(Elcr2)<<8)|inb(Elcr1); if(!(elcr & 0x2107)){ outb(Elcr1, 0); if(inb(Elcr1) == 0){ outb(Elcr1, 0x20); if(inb(Elcr1) == 0x20) i8259elcr = elcr; outb(Elcr1, elcr & 0xff); } } iunlock(&i8259lock); return vectorbase; } int i8259isr(int vno) { int irq, isr; if(vno < IdtPIC || vno > IdtPIC+15) return 0; irq = vno-IdtPIC; /* * Collect the interrupt status, * acknowledge the interrupt and return whether * the acknowledged interrupt was the correct * one (this could be better but it's not really * used). */ ilock(&i8259lock); isr = inb(Cntrl1+Isr); outb(Cntrl1+Ocw2, Ocw2sel|Eoi); if(irq >= 8){ isr |= inb(Cntrl2+Isr)<<8; outb(Cntrl2+Ocw2, Ocw2sel|Eoi); } iunlock(&i8259lock); return isr & (1<irq; if(irq < 0 || irq > 15){ print("i8259enable: irq %d out of range\n", irq); return -1; } irqbit = 1<>8) & 0xff); if(i8259elcr & irqbit) v->eoi = i8259isr; else v->isr = i8259isr; iunlock(&i8259lock); return IdtPIC+irq; } int i8259irqdisable(int irq) { int irqbit; /* * Given an IRQ, disable the corresponding interrupt * in the 8259. */ if(irq < 0 || irq > 15){ print("i8259disable: irq %d out of range\n", irq); return -1; } irqbit = 1<>8) & 0xff); } iunlock(&i8259lock); return 0; } #endif /* notdef */