/* $NetBSD: spkr.c,v 1.13 2003/07/15 01:26:32 lukem Exp $ */ /* * spkr.c -- device driver for console speaker on 80386 * * v1.1 by Eric S. Raymond (esr@snark.thyrsus.com) Feb 1990 * modified for 386bsd by Andrew A. Chernov * 386bsd only clean version, all SYSV stuff removed * use hz value from param.c */ #include __KERNEL_RCSID(0, "$NetBSD: spkr.c,v 1.13 2003/07/15 01:26:32 lukem Exp $"); #include "spkr.h" #if NSPKR > 0 #if NSPKR > 1 #error only one speaker device per system #endif #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include int spkrprobe __P((struct device *, struct cfdata *, void *)); void spkrattach __P((struct device *, struct device *, void *)); struct spkr_softc { struct device sc_dev; }; CFATTACH_DECL(spkr, sizeof(struct spkr_softc), spkrprobe, spkrattach, NULL, NULL); dev_type_open(spkropen); dev_type_close(spkrclose); dev_type_write(spkrwrite); dev_type_ioctl(spkrioctl); const struct cdevsw spkr_cdevsw = { spkropen, spkrclose, noread, spkrwrite, spkrioctl, nostop, notty, nopoll, nommap, nokqfilter, }; /**************** MACHINE DEPENDENT PART STARTS HERE ************************* * * This section defines a function tone() which causes a tone of given * frequency and duration from the 80x86's console speaker. * Another function endtone() is defined to force sound off, and there is * also a rest() entry point to do pauses. * * Audible sound is generated using the Programmable Interval Timer (PIT) and * Programmable Peripheral Interface (PPI) attached to the 80x86's speaker. The * PPI controls whether sound is passed through at all; the PIT's channel 2 is * used to generate clicks (a square wave) of whatever frequency is desired. */ /* * Magic numbers for timer control. */ #define PIT_MODE (TIMER_SEL2|TIMER_16BIT|TIMER_SQWAVE) static void endtone __P((void *)); static void tone __P((u_int, u_int)); static void rest __P((int)); static void playinit __P((void)); static void playtone __P((int, int, int)); static void playstring __P((char *, int)); static void endtone(v) void *v; { isa_outb(PITAUX_PORT, isa_inb(PITAUX_PORT) & ~PIT_SPKR); } static void tone(hz, ticks) /* emit tone of frequency hz for given number of ticks */ u_int hz, ticks; { u_int divisor = TIMER_DIV(hz); int sps; #ifdef DEBUG printf("tone: hz=%d ticks=%d\n", hz, ticks); #endif /* DEBUG */ /* set timer to generate clicks at given frequency in Hertz */ sps = spltty(); isa_outb(IO_TIMER1 + TIMER_MODE, PIT_MODE); /* prepare timer */ isa_outb(IO_TIMER1 + TIMER_CNTR2, (unsigned char) divisor); /* send lo byte */ isa_outb(IO_TIMER1 + TIMER_CNTR2, (divisor >> 8)); /* send hi byte */ splx(sps); /* turn the speaker on */ isa_outb(PITAUX_PORT, isa_inb(PITAUX_PORT) | PIT_SPKR); (void) tsleep(endtone, PZERO - 1, "spkrtone", ticks); } static void rest(ticks) /* rest for given number of ticks */ int ticks; { #ifdef DEBUG printf("rest: %d\n", ticks); #endif /* DEBUG */ (void) tsleep(rest, PZERO - 1, "spkrrest", ticks); } /**************** PLAY STRING INTERPRETER BEGINS HERE ********************** * * Play string interpretation is modelled on IBM BASIC 2.0's PLAY statement; * M[LNS] are missing and the ~ synonym and octave-tracking facility is added. * Requires tone(), rest(), and endtone(). String play is not interruptible * except possibly at physical block boundaries. */ typedef int bool; #define TRUE 1 #define FALSE 0 #define toupper(c) ((c) - ' ' * (((c) >= 'a') && ((c) <= 'z'))) #define isdigit(c) (((c) >= '0') && ((c) <= '9')) #define dtoi(c) ((c) - '0') static int octave; /* currently selected octave */ static int whole; /* whole-note time at current tempo, in ticks */ static int value; /* whole divisor for note time, quarter note = 1 */ static int fill; /* controls spacing of notes */ static bool octtrack; /* octave-tracking on? */ static bool octprefix; /* override current octave-tracking state? */ /* * Magic number avoidance... */ #define SECS_PER_MIN 60 /* seconds per minute */ #define WHOLE_NOTE 4 /* quarter notes per whole note */ #define MIN_VALUE 64 /* the most we can divide a note by */ #define DFLT_VALUE 4 /* default value (quarter-note) */ #define FILLTIME 8 /* for articulation, break note in parts */ #define STACCATO 6 /* 6/8 = 3/4 of note is filled */ #define NORMAL 7 /* 7/8ths of note interval is filled */ #define LEGATO 8 /* all of note interval is filled */ #define DFLT_OCTAVE 4 /* default octave */ #define MIN_TEMPO 32 /* minimum tempo */ #define DFLT_TEMPO 120 /* default tempo */ #define MAX_TEMPO 255 /* max tempo */ #define NUM_MULT 3 /* numerator of dot multiplier */ #define DENOM_MULT 2 /* denominator of dot multiplier */ /* letter to half-tone: A B C D E F G */ static int notetab[8] = {9, 11, 0, 2, 4, 5, 7}; /* * This is the American Standard A440 Equal-Tempered scale with frequencies * rounded to nearest integer. Thank Goddess for the good ol' CRC Handbook... * our octave 0 is standard octave 2. */ #define OCTAVE_NOTES 12 /* semitones per octave */ static int pitchtab[] = { /* C C# D D# E F F# G G# A A# B*/ /* 0 */ 65, 69, 73, 78, 82, 87, 93, 98, 103, 110, 117, 123, /* 1 */ 131, 139, 147, 156, 165, 175, 185, 196, 208, 220, 233, 247, /* 2 */ 262, 277, 294, 311, 330, 349, 370, 392, 415, 440, 466, 494, /* 3 */ 523, 554, 587, 622, 659, 698, 740, 784, 831, 880, 932, 988, /* 4 */ 1047, 1109, 1175, 1245, 1319, 1397, 1480, 1568, 1661, 1760, 1865, 1975, /* 5 */ 2093, 2217, 2349, 2489, 2637, 2794, 2960, 3136, 3322, 3520, 3729, 3951, /* 6 */ 4186, 4435, 4698, 4978, 5274, 5588, 5920, 6272, 6644, 7040, 7459, 7902, }; #define NOCTAVES (sizeof(pitchtab) / sizeof(pitchtab[0]) / OCTAVE_NOTES) static void playinit() { octave = DFLT_OCTAVE; whole = (hz * SECS_PER_MIN * WHOLE_NOTE) / DFLT_TEMPO; fill = NORMAL; value = DFLT_VALUE; octtrack = FALSE; octprefix = TRUE; /* act as though there was an initial O(n) */ } static void playtone(pitch, value, sustain) /* play tone of proper duration for current rhythm signature */ int pitch, value, sustain; { register int sound, silence, snum = 1, sdenom = 1; /* this weirdness avoids floating-point arithmetic */ for (; sustain; sustain--) { snum *= NUM_MULT; sdenom *= DENOM_MULT; } if (pitch == -1) rest(whole * snum / (value * sdenom)); else { sound = (whole * snum) / (value * sdenom) - (whole * (FILLTIME - fill)) / (value * FILLTIME); silence = whole * (FILLTIME-fill) * snum / (FILLTIME * value * sdenom); #ifdef DEBUG printf("playtone: pitch %d for %d ticks, rest for %d ticks\n", pitch, sound, silence); #endif /* DEBUG */ tone(pitchtab[pitch], sound); if (fill != LEGATO) rest(silence); } } static void playstring(cp, slen) /* interpret and play an item from a notation string */ char *cp; int slen; { int pitch, lastpitch = OCTAVE_NOTES * DFLT_OCTAVE; #define GETNUM(cp, v) for(v=0; slen > 0 && isdigit(cp[1]); ) \ {v = v * 10 + (*++cp - '0'); slen--;} for (; slen--; cp++) { int sustain, timeval, tempo; register char c = toupper(*cp); #ifdef DEBUG printf("playstring: %c (%x)\n", c, c); #endif /* DEBUG */ switch (c) { case 'A': case 'B': case 'C': case 'D': case 'E': case 'F': case 'G': /* compute pitch */ pitch = notetab[c - 'A'] + octave * OCTAVE_NOTES; /* this may be followed by an accidental sign */ if (slen > 0 && (cp[1] == '#' || cp[1] == '+')) { ++pitch; ++cp; slen--; } else if (slen > 0 && cp[1] == '-') { --pitch; ++cp; slen--; } /* * If octave-tracking mode is on, and there has been no octave- * setting prefix, find the version of the current letter note * closest to the last regardless of octave. */ if (octtrack && !octprefix) { if (abs(pitch-lastpitch) > abs(pitch+OCTAVE_NOTES-lastpitch)) { ++octave; pitch += OCTAVE_NOTES; } if (abs(pitch-lastpitch) > abs((pitch-OCTAVE_NOTES)-lastpitch)) { --octave; pitch -= OCTAVE_NOTES; } } octprefix = FALSE; lastpitch = pitch; /* ...which may in turn be followed by an override time value */ GETNUM(cp, timeval); if (timeval <= 0 || timeval > MIN_VALUE) timeval = value; /* ...and/or sustain dots */ for (sustain = 0; slen > 0 && cp[1] == '.'; cp++) { slen--; sustain++; } /* time to emit the actual tone */ playtone(pitch, timeval, sustain); break; case 'O': if (slen > 0 && (cp[1] == 'N' || cp[1] == 'n')) { octprefix = octtrack = FALSE; ++cp; slen--; } else if (slen > 0 && (cp[1] == 'L' || cp[1] == 'l')) { octtrack = TRUE; ++cp; slen--; } else { GETNUM(cp, octave); if (octave >= NOCTAVES) octave = DFLT_OCTAVE; octprefix = TRUE; } break; case '>': if (octave < NOCTAVES - 1) octave++; octprefix = TRUE; break; case '<': if (octave > 0) octave--; octprefix = TRUE; break; case 'N': GETNUM(cp, pitch); for (sustain = 0; slen > 0 && cp[1] == '.'; cp++) { slen--; sustain++; } playtone(pitch - 1, value, sustain); break; case 'L': GETNUM(cp, value); if (value <= 0 || value > MIN_VALUE) value = DFLT_VALUE; break; case 'P': case '~': /* this may be followed by an override time value */ GETNUM(cp, timeval); if (timeval <= 0 || timeval > MIN_VALUE) timeval = value; for (sustain = 0; slen > 0 && cp[1] == '.'; cp++) { slen--; sustain++; } playtone(-1, timeval, sustain); break; case 'T': GETNUM(cp, tempo); if (tempo < MIN_TEMPO || tempo > MAX_TEMPO) tempo = DFLT_TEMPO; whole = (hz * SECS_PER_MIN * WHOLE_NOTE) / tempo; break; case 'M': if (slen > 0 && (cp[1] == 'N' || cp[1] == 'n')) { fill = NORMAL; ++cp; slen--; } else if (slen > 0 && (cp[1] == 'L' || cp[1] == 'l')) { fill = LEGATO; ++cp; slen--; } else if (slen > 0 && (cp[1] == 'S' || cp[1] == 's')) { fill = STACCATO; ++cp; slen--; } break; } } } /******************* UNIX DRIVER HOOKS BEGIN HERE ************************** * * This section implements driver hooks to run playstring() and the tone(), * endtone(), and rest() functions defined above. */ static int spkr_active; /* exclusion flag */ static void *spkr_inbuf; int spkrprobe (parent, match, aux) struct device *parent; struct cfdata *match; void *aux; { /* * We only attach to the keyboard controller via * the console drivers. (We really wish we could be the * child of a real keyboard controller driver.) */ if ((parent == NULL) || (strcmp(parent->dv_cfdata->cf_name, "pc") != 0)) return (0); if (match->cf_loc[PCKBDCF_PORT] != PITAUX_PORT) return (0); return (1); } static int spkr_attached = 0; void spkrattach(parent, self, aux) struct device *parent; struct device *self; void *aux; { printf(" port 0x%x\n", self->dv_cfdata->cf_loc[PCKBDCF_PORT]); spkr_attached = 1; } int spkropen(dev, flags, mode, p) dev_t dev; int flags; int mode; struct proc *p; { #ifdef DEBUG printf("spkropen: entering with dev = %x\n", dev); #endif /* DEBUG */ if (minor(dev) != 0 || !spkr_attached) return(ENXIO); else if (spkr_active) return(EBUSY); else { playinit(); spkr_inbuf = malloc(DEV_BSIZE, M_DEVBUF, M_WAITOK); spkr_active = 1; } return(0); } int spkrwrite(dev, uio, flags) dev_t dev; struct uio *uio; int flags; { register int n; int error; #ifdef DEBUG printf("spkrwrite: entering with dev = %x, count = %d\n", dev, uio->uio_resid); #endif /* DEBUG */ if (minor(dev) != 0) return(ENXIO); else { n = min(DEV_BSIZE, uio->uio_resid); error = uiomove(spkr_inbuf, n, uio); if (!error) playstring((char *)spkr_inbuf, n); return(error); } } int spkrclose(dev, flags, mode, p) dev_t dev; int flags; int mode; struct proc *p; { #ifdef DEBUG printf("spkrclose: entering with dev = %x\n", dev); #endif /* DEBUG */ if (minor(dev) != 0) return(ENXIO); else { endtone(NULL); free(spkr_inbuf, M_DEVBUF); spkr_active = 0; } return(0); } int spkrioctl(dev, cmd, data, flag, p) dev_t dev; u_long cmd; caddr_t data; int flag; struct proc *p; { #ifdef DEBUG printf("spkrioctl: entering with dev = %x, cmd = %lx\n", dev, cmd); #endif /* DEBUG */ if (minor(dev) != 0) return(ENXIO); else if (cmd == SPKRTONE) { tone_t *tp = (tone_t *)data; if (tp->frequency == 0) rest(tp->duration); else tone(tp->frequency, tp->duration); } else if (cmd == SPKRTUNE) { tone_t *tp = (tone_t *)(*(caddr_t *)data); tone_t ttp; int error; for (; ; tp++) { error = copyin(tp, &ttp, sizeof(tone_t)); if (error) return(error); if (ttp.duration == 0) break; if (ttp.frequency == 0) rest(ttp.duration); else tone(ttp.frequency, ttp.duration); } } else return(EINVAL); return(0); } #endif /* NSPEAKER > 0 */ /* spkr.c ends here */