| blob | 36f52ddec509c272ef61ba5150425d5f3c1db3aa |
1 /*
2 * Copyright (C) 2000 - 2007 Jeff Dike (jdike@{addtoit,linux.intel}.com)
3 * Licensed under the GPL
4 * Derived (i.e. mostly copied) from arch/i386/kernel/irq.c:
5 * Copyright (C) 1992, 1998 Linus Torvalds, Ingo Molnar
6 */
20 /*
21 * Generic, controller-independent functions:
22 */
25 {
35 }
43 #ifndef CONFIG_SMP
45 #else
48 #endif
56 skip:
62 }
64 /*
65 * This list is accessed under irq_lock, except in sigio_handler,
66 * where it is safe from being modified. IRQ handlers won't change it -
67 * if an IRQ source has vanished, it will be freed by free_irqs just
68 * before returning from sigio_handler. That will process a separate
69 * list of irqs to free, with its own locking, coming back here to
70 * remove list elements, taking the irq_lock to do so.
71 */
78 {
91 }
98 }
99 }
100 }
103 }
108 {
141 dev_id);
143 }
144 }
157 /*
158 * n > 0
159 * It means we couldn't put new pollfd to current pollfds
160 * and tmp_fds is NULL or too small for new pollfds array.
161 * Needed size is equal to n as minimum.
162 *
163 * Here we have to drop the lock in order to call
164 * kmalloc, which might sleep.
165 * If something else came in and changed the pollfds array
166 * so we will not be able to put new pollfd struct to pollfds
167 * then we free the buffer tmp_fds and try again.
168 */
177 }
184 /*
185 * This calls activate_fd, so it has to be outside the critical
186 * section.
187 */
192 out_unlock:
194 out_kfree:
196 out:
198 }
201 {
207 }
212 };
215 {
219 }
222 {
227 }
230 {
232 }
235 {
237 }
239 /* Must be called with irq_lock held */
241 {
249 i++;
250 }
253 fd);
255 }
263 }
265 out:
267 }
270 {
280 }
285 }
288 {
298 }
304 }
306 /*
307 * Called just before shutdown in order to provide a clean exec
308 * environment in case the system is rebooting. No locking because
309 * that would cause a pointless shutdown hang if something hadn't
310 * released the lock.
311 */
313 {
321 }
322 /* If there is a signal already queued, after unblocking ignore it */
326 }
328 /*
329 * do_IRQ handles all normal device IRQs (the special
330 * SMP cross-CPU interrupts have their own specific
331 * handlers).
332 */
334 {
341 }
344 irq_handler_t handler,
347 {
354 }
357 }
362 /*
363 * irq_chip must define (startup || enable) &&
364 * (shutdown || disable) && end
365 */
367 {
368 }
370 /* This is used for everything else than the timer. */
378 };
388 };
391 {
405 }
406 }
408 /*
409 * IRQ stack entry and exit:
410 *
411 * Unlike i386, UML doesn't receive IRQs on the normal kernel stack
412 * and switch over to the IRQ stack after some preparation. We use
413 * sigaltstack to receive signals on a separate stack from the start.
414 * These two functions make sure the rest of the kernel won't be too
415 * upset by being on a different stack. The IRQ stack has a
416 * thread_info structure at the bottom so that current et al continue
417 * to work.
418 *
419 * to_irq_stack copies the current task's thread_info to the IRQ stack
420 * thread_info and sets the tasks's stack to point to the IRQ stack.
421 *
422 * from_irq_stack copies the thread_info struct back (flags may have
423 * been modified) and resets the task's stack pointer.
424 *
425 * Tricky bits -
426 *
427 * What happens when two signals race each other? UML doesn't block
428 * signals with sigprocmask, SA_DEFER, or sa_mask, so a second signal
429 * could arrive while a previous one is still setting up the
430 * thread_info.
431 *
432 * There are three cases -
433 * The first interrupt on the stack - sets up the thread_info and
434 * handles the interrupt
435 * A nested interrupt interrupting the copying of the thread_info -
436 * can't handle the interrupt, as the stack is in an unknown state
437 * A nested interrupt not interrupting the copying of the
438 * thread_info - doesn't do any setup, just handles the interrupt
439 *
440 * The first job is to figure out whether we interrupted stack setup.
441 * This is done by xchging the signal mask with thread_info->pending.
442 * If the value that comes back is zero, then there is no setup in
443 * progress, and the interrupt can be handled. If the value is
444 * non-zero, then there is stack setup in progress. In order to have
445 * the interrupt handled, we leave our signal in the mask, and it will
446 * be handled by the upper handler after it has set up the stack.
447 *
448 * Next is to figure out whether we are the outer handler or a nested
449 * one. As part of setting up the stack, thread_info->real_thread is
450 * set to non-NULL (and is reset to NULL on exit). This is the
451 * nesting indicator. If it is non-NULL, then the stack is already
452 * set up and the handler can run.
453 */
458 {
465 /*
466 * If any interrupts come in at this point, we want to
467 * make sure that their bits aren't lost by our
468 * putting our bit in. So, this loop accumulates bits
469 * until xchg returns the same value that we put in.
470 * When that happens, there were no new interrupts,
471 * and pending_mask contains a bit for each interrupt
472 * that came in.
473 */
480 }
494 }
499 }
502 {
517 }