b20667b35b
Lots of cleanup: - moved B_NO_ENABLE_COUNTER flag definition out of int.h to KernelExport.h, as it's described in the BeBook (although it's probably not really used that often :)) - int.c no longer has any platform dependent code (+ 0x20 on interrupt numbers is gone); it's now entirely handled in the arch/x86/ section. - the io_vectors[] is now statically initialized, instead of allocated from the heap - removed {install|remove}_interrupt_handler(); they weren't that useful, arch_smp_init() is now calling install_io_interrupt_handler() correctly instead - introduced a new arch_int.h header file that currently contains NUM_IO_VECTORS only (though on x86, it also has ARCH_INTERRUPT_BASE == 0x20). - changed the return type from {install|remove}_io_interrupt_handler() from "long" to "status_t" - rearranged and cleaned the PIC initialization code, made the PIC code more prominent - changed comments that talk about a non existing 8239 (the PIC chip is actually 8259) - moved arch/x86/interrupts.h to the source directory, as it's not used outside - added BeOS compatible interrupts_enabled() function, that should replace our equivalent (and private) are_interrupts_enabled() git-svn-id: file:///srv/svn/repos/haiku/haiku/trunk@12477 a95241bf-73f2-0310-859d-f6bbb57e9c96
236 lines
5.8 KiB
C
236 lines
5.8 KiB
C
/*
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* Copyright 2002-2005, Axel Dörfler, axeld@pinc-software.de. All rights reserved.
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* Distributed under the terms of the MIT License.
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*
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* Copyright 2001-2002, Travis Geiselbrecht. All rights reserved.
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* Distributed under the terms of the NewOS License.
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*/
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#include <int.h>
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#include <smp.h>
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#include <util/kqueue.h>
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#include <boot/kernel_args.h>
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#include <arch/int.h>
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#include <string.h>
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#include <stdio.h>
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#include <malloc.h>
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//#define TRACE_INT
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#ifdef TRACE_INT
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# define TRACE(x) dprintf x
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#else
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# define TRACE(x) ;
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#endif
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struct io_handler {
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struct io_handler *next;
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struct io_handler *prev;
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interrupt_handler func;
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void *data;
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bool use_enable_counter;
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};
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struct io_vector {
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struct io_handler handler_list;
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spinlock vector_lock;
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int32 enable_count;
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};
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static struct io_vector io_vectors[NUM_IO_VECTORS];
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cpu_status
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disable_interrupts(void)
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{
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return arch_int_disable_interrupts();
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}
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void
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restore_interrupts(cpu_status status)
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{
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arch_int_restore_interrupts(status);
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}
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bool
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interrupts_enabled(void)
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{
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return arch_int_are_interrupts_enabled();
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}
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status_t
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int_init(kernel_args *args)
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{
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dprintf("init_int_handlers: entry\n");
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return arch_int_init(args);
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}
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status_t
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int_init_post_vm(kernel_args *args)
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{
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int i;
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/* initialize the vector list */
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for (i = 0; i < NUM_IO_VECTORS; i++) {
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io_vectors[i].vector_lock = 0; /* initialize spinlock */
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io_vectors[i].enable_count = 0;
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initque(&io_vectors[i].handler_list); /* initialize handler queue */
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}
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return arch_int_init_post_vm(args);
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}
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/** Install a handler to be called when an interrupt is triggered
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* for the given interrupt number with \a data as the argument.
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*/
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status_t
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install_io_interrupt_handler(long vector, interrupt_handler handler, void *data, ulong flags)
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{
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struct io_handler *io = NULL;
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cpu_status state;
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if (vector < 0 || vector >= NUM_IO_VECTORS)
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return B_BAD_VALUE;
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io = (struct io_handler *)malloc(sizeof(struct io_handler));
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if (io == NULL)
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return B_NO_MEMORY;
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io->func = handler;
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io->data = data;
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io->use_enable_counter = (flags & B_NO_ENABLE_COUNTER) == 0;
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// Disable the interrupts, get the spinlock for this irq only
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// and then insert the handler
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state = disable_interrupts();
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acquire_spinlock(&io_vectors[vector].vector_lock);
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insque(io, &io_vectors[vector].handler_list);
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// If B_NO_ENABLE_COUNTER is set, we're being asked to not alter
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// whether the interrupt should be enabled or not
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if (io->use_enable_counter) {
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if (io_vectors[vector].enable_count++ == 0)
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arch_int_enable_io_interrupt(vector);
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}
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release_spinlock(&io_vectors[vector].vector_lock);
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restore_interrupts(state);
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return B_OK;
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}
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/** Remove a previously installed interrupt handler */
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status_t
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remove_io_interrupt_handler(long vector, interrupt_handler handler, void *data)
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{
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status_t status = B_BAD_VALUE;
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struct io_handler *io = NULL;
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cpu_status state;
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if (vector < 0 || vector >= NUM_IO_VECTORS)
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return B_BAD_VALUE;
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/* lock the structures down so it is not modified while we search */
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state = disable_interrupts();
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acquire_spinlock(&io_vectors[vector].vector_lock);
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/* loop through the available handlers and try to find a match.
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* We go forward through the list but this means we start with the
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* most recently added handlers.
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*/
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for (io = io_vectors[vector].handler_list.next;
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io != &io_vectors[vector].handler_list;
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io = io->next) {
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/* we have to match both function and data */
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if (io->func == handler && io->data == data) {
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remque(io);
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// Check if we need to disable the interrupt
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if (io->use_enable_counter && --io_vectors[vector].enable_count == 0)
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arch_int_disable_io_interrupt(vector);
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status = B_OK;
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break;
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}
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}
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release_spinlock(&io_vectors[vector].vector_lock);
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restore_interrupts(state);
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// if the handler could be found and removed, we still have to free it
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if (status == B_OK)
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free(io);
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return status;
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}
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/** actually process an interrupt via the handlers registered for that
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* vector (irq)
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*/
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int
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int_io_interrupt_handler(int vector)
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{
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int status = B_UNHANDLED_INTERRUPT;
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struct io_handler *io;
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acquire_spinlock(&io_vectors[vector].vector_lock);
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// The list can be empty at this place
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if (io_vectors[vector].handler_list.next == &io_vectors[vector].handler_list) {
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dprintf("unhandled io interrupt %d\n", vector);
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release_spinlock(&io_vectors[vector].vector_lock);
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return B_UNHANDLED_INTERRUPT;
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}
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/* Loop through the list of handlers.
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* each handler returns as follows...
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* - B_UNHANDLED_INTERRUPT, the interrupt wasn't processed by the
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* fucntion, so try the next available.
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* - B_HANDLED_INTERRUPT, the interrupt has been handled and no further
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* attention is required
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* - B_INVOKE_SCHEDULER, the interrupt has been handled, but the function wants
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* the scheduler to be invoked
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*
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* This is a change of behaviour from newos where every handler registered
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* be called, even if the interrupt had been "handled" by a previous
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* function.
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* The logic now is that if there are no handlers then we return
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* B_UNHANDLED_INTERRUPT and let the system do as it will.
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* When we have the first function that claims to have "handled" the
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* interrupt, by returning B_HANDLED_... or B_INVOKE_SCHEDULER we simply
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* stop calling further handlers and return the value from that
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* handler.
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* This may not be correct but appears to be what BeOS did and seems
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* right.
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*
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* ToDo: we might want to reenable calling all registered handlers depending
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* on a flag somewhere, so that we can deal with buggy drivers
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*/
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for (io = io_vectors[vector].handler_list.next;
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io != &io_vectors[vector].handler_list; // Are we already at the end of the list?
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io = io->next) {
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if ((status = io->func(io->data)) != B_UNHANDLED_INTERRUPT)
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break;
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}
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release_spinlock(&io_vectors[vector].vector_lock);
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return status;
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}
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