/* * Copyright (c) 1993-1995, 1999-2000 Apple Computer, Inc. * All rights reserved. * * @APPLE_LICENSE_HEADER_START@ * * The contents of this file constitute Original Code as defined in and * are subject to the Apple Public Source License Version 1.1 (the * "License"). You may not use this file except in compliance with the * License. Please obtain a copy of the License at * http://www.apple.com/publicsource and read it before using this file. * * This Original Code and all software distributed under the License are * distributed on an "AS IS" basis, WITHOUT WARRANTY OF ANY KIND, EITHER * EXPRESS OR IMPLIED, AND APPLE HEREBY DISCLAIMS ALL SUCH WARRANTIES, * INCLUDING WITHOUT LIMITATION, ANY WARRANTIES OF MERCHANTABILITY, * FITNESS FOR A PARTICULAR PURPOSE OR NON-INFRINGEMENT. Please see the * License for the specific language governing rights and limitations * under the License. * * @APPLE_LICENSE_HEADER_END@ */ /* * Timer interrupt callout module. * * HISTORY * * 20 December 2000 (debo) * Created. */ #include #include #include #include #include decl_simple_lock_data(static,timer_call_lock) static queue_head_t delayed_call_queues[NCPUS]; static struct { int delayed_num, delayed_hiwat; } timer_calls; static boolean_t timer_call_initialized = FALSE; static void timer_call_interrupt( uint64_t timestamp); #define qe(x) ((queue_entry_t)(x)) #define TC(x) ((timer_call_t)(x)) void timer_call_initialize(void) { spl_t s; int i; if (timer_call_initialized) panic("timer_call_initialize"); simple_lock_init(&timer_call_lock, ETAP_MISC_TIMER); s = splclock(); simple_lock(&timer_call_lock); for (i = 0; i < NCPUS; i++) queue_init(&delayed_call_queues[i]); clock_set_timer_func((clock_timer_func_t)timer_call_interrupt); timer_call_initialized = TRUE; simple_unlock(&timer_call_lock); splx(s); } void timer_call_setup( timer_call_t call, timer_call_func_t func, timer_call_param_t param0) { call_entry_setup(call, func, param0); } static __inline__ void _delayed_call_enqueue( queue_t queue, timer_call_t call) { timer_call_t current; current = TC(queue_first(queue)); while (TRUE) { if ( queue_end(queue, qe(current)) || call->deadline < current->deadline ) { current = TC(queue_prev(qe(current))); break; } current = TC(queue_next(qe(current))); } insque(qe(call), qe(current)); if (++timer_calls.delayed_num > timer_calls.delayed_hiwat) timer_calls.delayed_hiwat = timer_calls.delayed_num; call->state = DELAYED; } static __inline__ void _delayed_call_dequeue( timer_call_t call) { (void)remque(qe(call)); timer_calls.delayed_num--; call->state = IDLE; } static __inline__ void _set_delayed_call_timer( timer_call_t call) { clock_set_timer_deadline(call->deadline); } boolean_t timer_call_enter( timer_call_t call, uint64_t deadline) { boolean_t result = TRUE; queue_t delayed; spl_t s; s = splclock(); simple_lock(&timer_call_lock); if (call->state == DELAYED) _delayed_call_dequeue(call); else result = FALSE; call->param1 = 0; call->deadline = deadline; delayed = &delayed_call_queues[cpu_number()]; _delayed_call_enqueue(delayed, call); if (queue_first(delayed) == qe(call)) _set_delayed_call_timer(call); simple_unlock(&timer_call_lock); splx(s); return (result); } boolean_t timer_call_enter1( timer_call_t call, timer_call_param_t param1, uint64_t deadline) { boolean_t result = TRUE; queue_t delayed; spl_t s; s = splclock(); simple_lock(&timer_call_lock); if (call->state == DELAYED) _delayed_call_dequeue(call); else result = FALSE; call->param1 = param1; call->deadline = deadline; delayed = &delayed_call_queues[cpu_number()]; _delayed_call_enqueue(delayed, call); if (queue_first(delayed) == qe(call)) _set_delayed_call_timer(call); simple_unlock(&timer_call_lock); splx(s); return (result); } boolean_t timer_call_cancel( timer_call_t call) { boolean_t result = TRUE; spl_t s; s = splclock(); simple_lock(&timer_call_lock); if (call->state == DELAYED) _delayed_call_dequeue(call); else result = FALSE; simple_unlock(&timer_call_lock); splx(s); return (result); } boolean_t timer_call_is_delayed( timer_call_t call, uint64_t *deadline) { boolean_t result = FALSE; spl_t s; s = splclock(); simple_lock(&timer_call_lock); if (call->state == DELAYED) { if (deadline != NULL) *deadline = call->deadline; result = TRUE; } simple_unlock(&timer_call_lock); splx(s); return (result); } /* * Called at splclock. */ void timer_call_shutdown( processor_t processor) { timer_call_t call; queue_t delayed, delayed1; assert(processor != current_processor()); delayed = &delayed_call_queues[processor->slot_num]; delayed1 = &delayed_call_queues[cpu_number()]; simple_lock(&timer_call_lock); call = TC(queue_first(delayed)); while (!queue_end(delayed, qe(call))) { _delayed_call_dequeue(call); _delayed_call_enqueue(delayed1, call); call = TC(queue_first(delayed)); } call = TC(queue_first(delayed1)); if (!queue_end(delayed1, qe(call))) _set_delayed_call_timer(call); simple_unlock(&timer_call_lock); } static void timer_call_interrupt( uint64_t timestamp) { timer_call_t call; queue_t delayed = &delayed_call_queues[cpu_number()]; simple_lock(&timer_call_lock); call = TC(queue_first(delayed)); while (!queue_end(delayed, qe(call))) { if (call->deadline <= timestamp) { timer_call_func_t func; timer_call_param_t param0, param1; _delayed_call_dequeue(call); func = call->func; param0 = call->param0; param1 = call->param1; simple_unlock(&timer_call_lock); (*func)(param0, param1); simple_lock(&timer_call_lock); } else break; call = TC(queue_first(delayed)); } if (!queue_end(delayed, qe(call))) _set_delayed_call_timer(call); simple_unlock(&timer_call_lock); }