/* * APM (Advanced Power Management) BIOS Device Driver * * Copyright (c) 1994 UKAI, Fumitoshi. * Copyright (c) 1994-1995 by HOSOKAWA, Tatsumi * * This software may be used, modified, copied, and distributed, in * both source and binary form provided that the above copyright and * these terms are retained. Under no circumstances is the author * responsible for the proper functioning of this software, nor does * the author assume any responsibility for damages incurred with its * use. * * Sep, 1994 Implemented on FreeBSD 1.1.5.1R (Toshiba AVS001WD) * * $Id: apm.c,v 1.10 1994/12/16 07:31:47 phk Exp $ */ #include "apm.h" #if NAPM > 0 #ifdef __FreeBSD__ #include #include "conf.h" #include #include #include #include #include #include #include #include #include "i386/isa/isa.h" #include "i386/isa/isa_device.h" #include #include #include #include #include #include "apm_setup.h" #endif /* __FreeBSD__ */ #ifdef MACH_KERNEL #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #endif /* MACH_KERNEL */ /* static data */ struct apm_softc { int initialized, active, halt_cpu; u_int minorversion, majorversion; u_int cs32_base, cs16_base, ds_base; u_int cs_limit, ds_limit; u_int cs_entry; u_int intversion; int idle_cpu, disabled, disengaged; struct apmhook sc_suspend; struct apmhook sc_resume; }; static struct apm_softc apm_softc[NAPM]; static struct apm_softc *master_softc = NULL; /* XXX */ struct apmhook *hook[NAPM_HOOK]; /* XXX */ #ifdef APM_SLOWSTART int apm_slowstart = 0; int apm_ss_cnt = 0; static int apm_slowstart_p = 0; int apm_slowstart_stat = 0; #endif /* APM_SLOWSTART */ #ifdef MACH_KERNEL extern struct fake_descriptor gdt[GDTSZ]; extern void fix_desc(struct fake_descriptor *, int); #endif /* MACH_KERNEL */ #define is_enabled(foo) ((foo) ? "enabled" : "disabled") /* Map version number to integer (keeps ordering of version numbers) */ #define INTVERSION(major, minor) ((major)*100 + (minor)) #ifdef __FreeBSD__ static timeout_t apm_timeout; #endif /* __FreeBSD__ */ #ifdef MACH_KERNEL static void apm_timeout(void *); #endif /* MACH_KERNEL */ /* setup APM GDT discriptors */ static void setup_apm_gdt(u_int code32_base, u_int code16_base, u_int data_base, u_int code_limit, u_int data_limit) { #ifdef __FreeBSD__ /* setup 32bit code segment */ gdt_segs[GAPMCODE32_SEL].ssd_base = code32_base; gdt_segs[GAPMCODE32_SEL].ssd_limit = code_limit; /* setup 16bit code segment */ gdt_segs[GAPMCODE16_SEL].ssd_base = code16_base; gdt_segs[GAPMCODE16_SEL].ssd_limit = code_limit; /* setup data segment */ gdt_segs[GAPMDATA_SEL ].ssd_base = data_base; gdt_segs[GAPMDATA_SEL ].ssd_limit = data_limit; /* reflect these changes on physical GDT */ ssdtosd(gdt_segs + GAPMCODE32_SEL, &gdt[GAPMCODE32_SEL].sd); ssdtosd(gdt_segs + GAPMCODE16_SEL, &gdt[GAPMCODE16_SEL].sd); ssdtosd(gdt_segs + GAPMDATA_SEL , &gdt[GAPMDATA_SEL ].sd); #endif /* __FreeBSD__ */ #ifdef MACH_KERNEL /* setup 32bit code segment */ gdt[sel_idx(GAPMCODE32_SEL)].offset = code32_base; gdt[sel_idx(GAPMCODE32_SEL)].lim_or_seg = code_limit; gdt[sel_idx(GAPMCODE32_SEL)].size_or_wdct = SZ_32; gdt[sel_idx(GAPMCODE32_SEL)].access = ACC_P | ACC_PL_K | ACC_CODE_R; /* setup 16bit code segment */ gdt[sel_idx(GAPMCODE16_SEL)].offset = code16_base; gdt[sel_idx(GAPMCODE16_SEL)].lim_or_seg = code_limit; gdt[sel_idx(GAPMCODE16_SEL)].size_or_wdct = 0; gdt[sel_idx(GAPMCODE16_SEL)].access = ACC_P | ACC_PL_K | ACC_CODE_R; /* setup data segment */ gdt[sel_idx(GAPMDATA_SEL )].offset = data_base; gdt[sel_idx(GAPMDATA_SEL )].lim_or_seg = data_limit; gdt[sel_idx(GAPMDATA_SEL )].size_or_wdct = 0; gdt[sel_idx(GAPMDATA_SEL )].access = ACC_P | ACC_PL_K | ACC_DATA_W; /* reflect these changes on physical GDT */ fix_desc(gdt + sel_idx(GAPMCODE32_SEL), 1); fix_desc(gdt + sel_idx(GAPMCODE16_SEL), 1); fix_desc(gdt + sel_idx(GAPMDATA_SEL) , 1); #endif /* MACH_KERNEL */ } /* 48bit far pointer */ struct addr48 { u_long offset; u_short segment; } apm_addr; int apm_errno; inline int apm_int(u_long *eax, u_long *ebx, u_long *ecx) { u_long cf; __asm ("pushl %%ebp pushl %%edx pushl %%esi xorl %3,%3 movl %3,%%esi lcall _apm_addr jnc 1f incl %3 1: popl %%esi popl %%edx popl %%ebp" : "=a" (*eax), "=b" (*ebx), "=c" (*ecx), "=D" (cf) : "0" (*eax), "1" (*ebx), "2" (*ecx) ); apm_errno = ((*eax) >> 8) & 0xff; return cf; } /* enable/disable power management */ static int apm_enable_disable_pm(struct apm_softc *sc, int enable) { u_long eax, ebx, ecx; eax = (APM_BIOS << 8) | APM_ENABLEDISABLEPM; if (sc->intversion >= INTVERSION(1, 1)) { ebx = PMDV_ALLDEV; } else { ebx = 0xffff; /* APM version 1.0 only */ } ecx = enable; return apm_int(&eax, &ebx, &ecx); } /* Tell APM-BIOS that WE will do 1.1 and see what they say... */ static void apm_driver_version(void) { u_long eax, ebx, ecx, i; #ifdef APM_DEBUG eax = (APM_BIOS<<8) | APM_INSTCHECK; ebx = 0x0; ecx = 0x0101; i = apm_int(&eax, &ebx, &ecx); printf("[%04lx %04lx %04lx %ld %02x]\n", eax, ebx, ecx, i, apm_errno); #endif eax = (APM_BIOS << 8) | APM_DRVVERSION; ebx = 0x0; ecx = 0x0101; if(!apm_int(&eax, &ebx, &ecx)) apm_version = eax & 0xffff; #ifdef APM_DEBUG eax = (APM_BIOS << 8) | APM_INSTCHECK; ebx = 0x0; ecx = 0x0101; i = apm_int(&eax, &ebx, &ecx); printf("[%04lx %04lx %04lx %ld %02x]\n", eax, ebx, ecx, i, apm_errno); #endif } /* engage/disengage power management (APM 1.1 or later) */ static int apm_engage_disengage_pm(struct apm_softc *sc, int engage) { u_long eax, ebx, ecx, i; eax = (APM_BIOS << 8) | APM_ENGAGEDISENGAGEPM; ebx = PMDV_ALLDEV; ecx = engage; i = apm_int(&eax, &ebx, &ecx); return i; } /* get PM event */ static u_int apm_getevent(struct apm_softc *sc) { u_long eax, ebx, ecx; eax = (APM_BIOS << 8) | APM_GETPMEVENT; ebx = 0; ecx = 0; if (apm_int(&eax, &ebx, &ecx)) return PMEV_NOEVENT; return ebx & 0xffff; } /* suspend entire system */ static int apm_suspend_system(struct apm_softc *sc) { u_long eax, ebx, ecx; eax = (APM_BIOS << 8) | APM_SETPWSTATE; ebx = PMDV_ALLDEV; ecx = PMST_SUSPEND; __asm("cli"); if (apm_int(&eax, &ebx, &ecx)) { __asm("sti"); printf("Entire system suspend failure: errcode = %ld\n", 0xff & (eax >> 8)); return 1; } __asm("sti"); return 0; } /* Display control */ /* * Experimental implementation: My laptop machine can't handle this function * If your laptop can control the display via APM, please inform me. * HOSOKAWA, Tatsumi */ int apm_display_off(void) { u_long eax, ebx, ecx; eax = (APM_BIOS << 8) | APM_SETPWSTATE; ebx = PMDV_2NDSTORAGE0; ecx = PMST_STANDBY; if (apm_int(&eax, &ebx, &ecx)) { printf("Display off failure: errcode = %ld\n", 0xff & (eax >> 8)); return 1; } return 0; } /* APM Battery low handler */ static void apm_battery_low(struct apm_softc *sc) { printf("\007\007 * * * BATTERY IS LOW * * * \007\007"); } /* APM hook manager */ static struct apmhook * apm_add_hook(struct apmhook **list, struct apmhook *ah) { int s; struct apmhook *p, *prev; #if 0 printf("Add hook \"%s\"\n", ah->ah_name); #endif s = splhigh(); if (ah == NULL) { panic("illegal apm_hook!"); } prev = NULL; for (p = *list; p != NULL; prev = p, p = p->ah_next) { if (p->ah_order > ah->ah_order) { break; } } if (prev == NULL) { ah->ah_next = *list; *list = ah; } else { ah->ah_next = prev->ah_next; prev->ah_next = ah; } splx(s); return ah; } static void apm_del_hook(struct apmhook **list, struct apmhook *ah) { int s; struct apmhook *p, *prev; s = splhigh(); prev = NULL; for (p = *list; p != NULL; prev = p, p = p->ah_next) { if (p == ah) { goto deleteit; } } panic("Tried to delete unregistered apm_hook."); goto nosuchnode; deleteit: if (prev != NULL) { prev->ah_next = p->ah_next; } else { *list = p->ah_next; } nosuchnode: splx(s); } /* APM driver calls some functions automatically */ static void apm_execute_hook(struct apmhook *list) { struct apmhook *p; for (p = list; p != NULL; p = p->ah_next) { #if 0 printf("Execute APM hook \"%s.\"\n", p->ah_name); #endif if ((*(p->ah_fun))(p->ah_arg)) { printf("Warning: APM hook \"%s\" failed", p->ah_name); } } } /* establish an apm hook */ struct apmhook * apm_hook_establish(int apmh, struct apmhook *ah) { if (apmh < 0 || apmh >= NAPM_HOOK) return NULL; return apm_add_hook(&hook[apmh], ah); } /* disestablish an apm hook */ void apm_hook_disestablish(int apmh, struct apmhook *ah) { if (apmh < 0 || apmh >= NAPM_HOOK) return; apm_del_hook(&hook[apmh], ah); } static struct timeval suspend_time; static struct timeval diff_time; static int apm_default_resume(struct apm_softc *sc) { #ifdef __FreeBSD__ int pl; u_int second, minute, hour; struct timeval resume_time, tmp_time; /* modified for adjkerntz */ pl = splsoftclock(); inittodr(0); /* adjust time to RTC */ microtime(&resume_time); tmp_time = time; /* because 'time' is volatile */ timevaladd(&tmp_time, &diff_time); time = tmp_time; splx(pl); second = resume_time.tv_sec - suspend_time.tv_sec; hour = second / 3600; second %= 3600; minute = second / 60; second %= 60; log(LOG_NOTICE, "resumed from suspended mode (slept %02d:%02d:%02d)\n", hour, minute, second); #endif /* __FreeBSD__ */ return 0; } static int apm_default_suspend(void) { #ifdef __FreeBSD__ int pl; pl = splsoftclock(); microtime(&diff_time); inittodr(0); microtime(&suspend_time); timevalsub(&diff_time, &suspend_time); splx(pl); #if 0 printf("diff_time = %d:%d\n", diff_time.tv_sec, diff_time.tv_usec); #endif #endif /* __FreeBSD__ */ return 0; } static void apm_processevent(struct apm_softc *); /* * Public interface to the suspend/resume: * * Execute suspend and resume hook before and after sleep, respectively. * */ void apm_suspend(void) { struct apm_softc *sc; sc = master_softc; /* XXX */ if (!sc) return; if (sc->initialized) { apm_execute_hook(hook[APM_HOOK_SUSPEND]); apm_suspend_system(sc); apm_processevent(sc); } } void apm_resume(void) { struct apm_softc *sc; sc = master_softc; /* XXX */ if (!sc) return; if (sc->initialized) { apm_execute_hook(hook[APM_HOOK_RESUME]); } } /* get APM information */ static int apm_get_info(struct apm_softc *sc, apm_info_t aip) { u_long eax, ebx, ecx; eax = (APM_BIOS << 8) | APM_GETPWSTATUS; ebx = PMDV_ALLDEV; ecx = 0; if (apm_int(&eax, &ebx, &ecx)) return 1; aip->ai_acline = (ebx >> 8) & 0xff; aip->ai_batt_stat = ebx & 0xff; aip->ai_batt_life = ecx & 0xff; aip->ai_major = (u_int)sc->majorversion; aip->ai_minor = (u_int)sc->minorversion; return 0; } /* inform APM BIOS that CPU is idle */ void apm_cpu_idle(void) { struct apm_softc *sc = master_softc; /* XXX */ if (sc->idle_cpu) { if (sc->active) { __asm ("movw $0x5305, %ax; lcall _apm_addr"); } } /* * Some APM implementation halts CPU in BIOS, whenever * "CPU-idle" function are invoked, but swtch() of * FreeBSD halts CPU, therefore, CPU is halted twice * in the sched loop. It makes the interrupt latency * terribly long and be able to cause a serious problem * in interrupt processing. We prevent it by removing * "hlt" operation from swtch() and managed it under * APM driver. */ /* * UKAI Note: on NetBSD, idle() called from cpu_switch() * doesn't halt CPU, so halt_cpu may not need on NetBSD/i386 * or only "sti" operation would be needed. */ if (!sc->active || sc->halt_cpu) { __asm("sti ; hlt"); /* wait for interrupt */ } } /* inform APM BIOS that CPU is busy */ void apm_cpu_busy(void) { struct apm_softc *sc = master_softc; /* XXX */ if (sc->idle_cpu && sc->active) { __asm("movw $0x5306, %ax; lcall _apm_addr"); } } /* * APM timeout routine: * * This routine is automatically called by timer once per second. */ static void apm_timeout(void *arg) { struct apm_softc *sc = arg; apm_processevent(sc); timeout(apm_timeout, (void *)sc, hz - 1 ); /* More than 1 Hz */ } /* enable APM BIOS */ static void apm_event_enable(struct apm_softc *sc) { #ifdef APM_DEBUG printf("called apm_event_enable()\n"); #endif if (sc->initialized) { sc->active = 1; apm_timeout(sc); } } /* disable APM BIOS */ static void apm_event_disable(struct apm_softc *sc) { #ifdef APM_DEBUG printf("called apm_event_disable()\n"); #endif if (sc->initialized) { untimeout(apm_timeout, NULL); sc->active = 0; } } /* halt CPU in scheduling loop */ static void apm_halt_cpu(struct apm_softc *sc) { if (sc->initialized) { sc->halt_cpu = 1; } #ifdef APM_SLOWSTART apm_slowstart = 0; #endif /* APM_SLOWSTART */ } /* don't halt CPU in scheduling loop */ static void apm_not_halt_cpu(struct apm_softc *sc) { if (sc->initialized) { sc->halt_cpu = 0; } #ifdef APM_SLOWSTART apm_slowstart = apm_slowstart_p; #endif /* APM_SLOWSTART */ } /* device driver definitions */ #ifdef __FreeBSD__ int apmprobe (struct isa_device *); int apmattach(struct isa_device *); struct isa_driver apmdriver = { apmprobe, apmattach, "apm" }; #endif /* __FreeBSD__ */ #ifdef MACH_KERNEL int apmprobe(vm_offset_t, struct bus_ctlr *); void apmattach(struct bus_device *); static struct bus_device *apminfo[NAPM]; static vm_offset_t apmstd[NAPM] = { 0 }; struct bus_driver apmdriver = { apmprobe, 0, apmattach, 0, apmstd, "apm", apminfo, 0, 0, 0}; #endif /* MACH_KERNEL */ /* * probe APM (dummy): * * APM probing routine is placed on locore.s and apm_init.S because * this process forces the CPU to turn to real mode or V86 mode. * Current version uses real mode, but on future version, we want * to use V86 mode in APM initialization. */ int #ifdef __FreeBSD__ apmprobe(struct isa_device *dvp) #endif /* __FreeBSD__ */ #ifdef MACH_KERNEL apmprobe(vm_offset_t port, struct bus_ctlr *devc) #endif /* MACH_KERNEL */ { #ifdef __FreeBSD__ int unit = dvp->id_unit; #endif /* __FreeBSD__ */ #ifdef MACH_KERNEL int unit = devc->unit; #endif /* MACH_KERNEL */ struct apm_softc *sc = &apm_softc[unit]; switch (apm_version) { case APMINI_CANTFIND: /* silent */ return 0; case APMINI_NOT32BIT: printf("apm%d: 32bit connection is not supported.\n", unit); return 0; case APMINI_CONNECTERR: printf("apm%d: 32-bit connection error.\n", unit); return 0; } return -1; } /* Process APM event */ static void apm_processevent(struct apm_softc *sc) { int apm_event; #ifdef APM_DEBUG # define OPMEV_DEBUGMESSAGE(symbol) case symbol: \ printf("Original APM Event: " #symbol "\n"); #else # define OPMEV_DEBUGMESSAGE(symbol) case symbol: #endif while (1) { apm_event = apm_getevent(sc); if (apm_event == PMEV_NOEVENT) break; switch (apm_event) { OPMEV_DEBUGMESSAGE(PMEV_STANDBYREQ); apm_suspend(); break; OPMEV_DEBUGMESSAGE(PMEV_SUSPENDREQ); apm_suspend(); break; OPMEV_DEBUGMESSAGE(PMEV_USERSUSPENDREQ); apm_suspend(); break; OPMEV_DEBUGMESSAGE(PMEV_CRITSUSPEND); apm_suspend(); break; OPMEV_DEBUGMESSAGE(PMEV_NORMRESUME); apm_resume(); break; OPMEV_DEBUGMESSAGE(PMEV_CRITRESUME); apm_resume(); break; OPMEV_DEBUGMESSAGE(PMEV_STANDBYRESUME); apm_resume(); break; OPMEV_DEBUGMESSAGE(PMEV_BATTERYLOW); apm_battery_low(sc); apm_suspend(); break; OPMEV_DEBUGMESSAGE(PMEV_POWERSTATECHANGE); break; OPMEV_DEBUGMESSAGE(PMEV_UPDATETIME); inittodr(0); /* adjust time to RTC */ break; default: printf("Unknown Original APM Event 0x%x\n", apm_event); break; } } } /* * Attach APM: * * Initialize APM driver (APM BIOS itself has been initialized in locore.s) * * Now, unless I'm mad, (not quite ruled out yet), the APM-1.1 spec is bogus: * * Appendix C says under the header "APM 1.0/APM 1.1 Modal BIOS Behavior" * that "When an APM Driver connects with an APM 1.1 BIOS, the APM 1.1 BIOS * will default to an APM 1.0 connection. After an APM Driver calls the APM * Driver Version function, specifying that it supports APM 1.1, and [sic!] * APM BIOS will change its behavior to an APM 1.1 connection. If the APM * BIOS is an APM 1.0 BIOS, the APM Driver Version function call will fail, * and the connection will remain an APM 1.0 connection." * * OK so I can establish a 1.0 connection, and then tell that I'm a 1.1 * and maybe then the BIOS will tell that it too is a 1.1. * Fine. * Now how will I ever get the segment-limits for instance ? There is no * way I can see that I can get a 1.1 response back from an "APM Protected * Mode 32-bit Interface Connect" function ??? * * Who made this, Intel and Microsoft ? -- How did you guess ! * * /phk */ #ifdef __FreeBSD__ int apmattach(struct isa_device *dvp) #endif /* __FreeBSD__ */ #ifdef MACH_KERNEL void apmattach(struct bus_device *dvp) #endif /* MACH_KERNEL */ { #ifdef __FreeBSD__ int unit = dvp->id_unit; #define APM_KERNBASE KERNBASE #endif /* __FreeBSD__ */ #ifdef MACH_KERNEL int unit = dvp->unit; #define APM_KERNBASE VM_MIN_KERNEL_ADDRESS #endif /* MACH_KERNEL */ struct apm_softc *sc = &apm_softc[unit]; int i; master_softc = sc; /* XXX */ sc->initialized = 0; sc->active = 0; sc->halt_cpu = 1; /* setup APM parameters */ sc->cs16_base = (apm_cs32_base << 4) + APM_KERNBASE; sc->cs32_base = (apm_cs16_base << 4) + APM_KERNBASE; sc->ds_base = (apm_ds_base << 4) + APM_KERNBASE; sc->cs_limit = apm_cs_limit; sc->ds_limit = apm_ds_limit; sc->cs_entry = apm_cs_entry; sc->idle_cpu = ((apm_flags & APM_CPUIDLE_SLOW) != 0); sc->disabled = ((apm_flags & APM_DISABLED) != 0); sc->disengaged = ((apm_flags & APM_DISENGAGED) != 0); #ifdef APM_SLOWSTART if (sc->idle_cpu) { apm_slowstart = apm_slowstart_p = 1; } #endif /* print bootstrap messages */ #ifdef APM_DEBUG printf(" found APM BIOS version %04x\n", apm_version); printf("apm%d: Code32 0x%08x, Code16 0x%08x, Data 0x%08x\n", unit, sc->cs32_base, sc->cs16_base, sc->ds_base); printf("apm%d: Code entry 0x%08x, Idling CPU %s, Management %s\n", unit, sc->cs_entry, is_enabled(sc->idle_cpu), is_enabled(!sc->disabled)); printf("apm%d: CS_limit=%x, DS_limit=%x\n", unit, sc->cs_limit, sc->ds_limit); #endif /* APM_DEBUG */ sc->cs_limit = 0xffff; sc->ds_limit = 0xffff; /* setup GDT */ setup_apm_gdt(sc->cs32_base, sc->cs16_base, sc->ds_base, sc->cs_limit, sc->ds_limit); /* setup entry point 48bit pointer */ #ifdef __FreeBSD__ apm_addr.segment = GSEL(GAPMCODE32_SEL, SEL_KPL); #endif /* __FreeBSD__ */ #ifdef MACH_KERNEL apm_addr.segment = GAPMCODE32_SEL; #endif /* MACH_KERNEL */ apm_addr.offset = sc->cs_entry; /* Try to kick bios into 1.1 mode */ apm_driver_version(); sc->minorversion = ((apm_version & 0x00f0) >> 4) * 10 + ((apm_version & 0x000f) >> 0); sc->majorversion = ((apm_version & 0xf000) >> 12) * 10 + ((apm_version & 0x0f00) >> 8); sc->intversion = INTVERSION(sc->majorversion, sc->minorversion); if (sc->intversion >= INTVERSION(1, 1)) { printf("apm%d: Engaged control %s\n", unit, is_enabled(!sc->disengaged)); } printf(" found APM BIOS version %d.%d\n", sc->majorversion, sc->minorversion); printf("apm%d: Idling CPU %s\n", unit, is_enabled(sc->idle_cpu)); /* enable power management */ if (sc->disabled) { if (apm_enable_disable_pm(sc, 1)) { printf("Warning: APM enable function failed! [%x]\n", apm_errno); } } /* engage power managment (APM 1.1 or later) */ if (sc->intversion >= INTVERSION(1, 1) && sc->disengaged) { if (apm_engage_disengage_pm(sc, 1)) { printf("Warning: APM engage function failed [%x]\n", apm_errno); } } /* default suspend hook */ sc->sc_suspend.ah_fun = apm_default_suspend; sc->sc_suspend.ah_arg = sc; sc->sc_suspend.ah_name = "default suspend"; sc->sc_suspend.ah_order = APM_MAX_ORDER; /* default resume hook */ sc->sc_resume.ah_fun = apm_default_resume; sc->sc_resume.ah_arg = sc; sc->sc_resume.ah_name = "default resume"; sc->sc_resume.ah_order = APM_MIN_ORDER; apm_hook_establish(APM_HOOK_SUSPEND, &sc->sc_suspend); apm_hook_establish(APM_HOOK_RESUME , &sc->sc_resume); apm_event_enable(sc); sc->initialized = 1; #ifdef __FreeBSD__ return 0; #endif /* __FreeBSD__ */ } #ifdef __FreeBSD__ int apmopen(dev_t dev, int flag, int fmt, struct proc *p) { struct apm_softc *sc = &apm_softc[minor(dev)]; if (minor(dev) >= NAPM) { return (ENXIO); } if (!sc->initialized) { return ENXIO; } return 0; } int apmclose(dev_t dev, int flag, int fmt, struct proc *p) { return 0; } int apmioctl(dev_t dev, int cmd, caddr_t addr, int flag, struct proc *p) { struct apm_softc *sc = &apm_softc[minor(dev)]; int error = 0; int pl; #ifdef APM_DEBUG printf("APM ioctl: minor = %d, cmd = 0x%x\n", minor(dev), cmd); #endif if (minor(dev) >= NAPM) { return ENXIO; } if (!sc->initialized) { return ENXIO; } switch (cmd) { case APMIO_SUSPEND: apm_suspend(); break; case APMIO_GETINFO: if (apm_get_info(sc, (apm_info_t)addr)) { error = ENXIO; } break; case APMIO_ENABLE: apm_event_enable(sc); break; case APMIO_DISABLE: apm_event_disable(sc); break; case APMIO_HALTCPU: apm_halt_cpu(sc); break; case APMIO_NOTHALTCPU: apm_not_halt_cpu(sc); break; case APMIO_DISPLAYOFF: if (apm_display_off()) { error = ENXIO; } break; default: error = EINVAL; break; } return error; } #endif /* __FreeBSD__ */ #ifdef MACH_KERNEL io_return_t apmopen(dev_t dev, int flag, io_req_t ior) { int result; result = ENXIO; return result; } io_return_t apmclose(dev_t dev, int flag) { return 0; } io_return_t apmgetstat(dev_t dev, int flavor, int *data, u_int *count) { } io_return_t apmsetstat(dev_t dev, int flavor, int *data, u_int count) { } #endif /* MACH_KERNEL */ #endif /* NAPM > 0 */