/* * QEMU Soundblaster 16 emulation * * Copyright (c) 2003-2004 Vassili Karpov (malc) * * Permission is hereby granted, free of charge, to any person obtaining a copy * of this software and associated documentation files (the "Software"), to deal * in the Software without restriction, including without limitation the rights * to use, copy, modify, merge, publish, distribute, sublicense, and/or sell * copies of the Software, and to permit persons to whom the Software is * furnished to do so, subject to the following conditions: * * The above copyright notice and this permission notice shall be included in * all copies or substantial portions of the Software. * * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR * IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, * FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL * THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER * LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, * OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN * THE SOFTWARE. */ #include "vl.h" #define LENOFA(a) ((int) (sizeof(a)/sizeof(a[0]))) #define dolog(...) AUD_log ("sb16", __VA_ARGS__) #ifdef DEBUG #define ldebug(...) dolog (__VA_ARGS__) #else #define ldebug(...) #endif /* #define DEBUG */ /* #define DEBUG_SB16_MOST */ #define IO_READ_PROTO(name) \ uint32_t name (void *opaque, uint32_t nport) #define IO_WRITE_PROTO(name) \ void name (void *opaque, uint32_t nport, uint32_t val) static const char e3[] = "COPYRIGHT (C) CREATIVE TECHNOLOGY LTD, 1992."; static struct { int ver_lo; int ver_hi; int irq; int dma; int hdma; int port; } conf = {5, 4, 5, 1, 5, 0x220}; typedef struct SB16State { int irq; int dma; int hdma; int port; int ver; int in_index; int out_data_len; int fmt_stereo; int fmt_signed; int fmt_bits; audfmt_e fmt; int dma_auto; int block_size; int fifo; int freq; int time_const; int speaker; int needed_bytes; int cmd; int use_hdma; int highspeed; int can_write; int v2x6; uint8_t csp_param; uint8_t csp_value; uint8_t csp_mode; uint8_t csp_regs[256]; uint8_t csp_index; uint8_t csp_reg83[4]; int csp_reg83r; int csp_reg83w; uint8_t in2_data[10]; uint8_t out_data[50]; uint8_t test_reg; uint8_t last_read_byte; int nzero; int left_till_irq; int dma_running; int bytes_per_second; int align; SWVoice *voice; QEMUTimer *ts, *aux_ts; /* mixer state */ int mixer_nreg; uint8_t mixer_regs[256]; } SB16State; /* XXX: suppress that and use a context */ static struct SB16State dsp; static int magic_of_irq (int irq) { switch (irq) { case 5: return 2; case 7: return 4; case 9: return 1; case 10: return 8; default: dolog ("bad irq %d\n", irq); return 2; } } static int irq_of_magic (int magic) { switch (magic) { case 1: return 9; case 2: return 5; case 4: return 7; case 8: return 10; default: dolog ("bad irq magic %d\n", magic); return -1; } } #if 0 static void log_dsp (SB16State *dsp) { ldebug ("%s:%s:%d:%s:dmasize=%d:freq=%d:const=%d:speaker=%d\n", dsp->fmt_stereo ? "Stereo" : "Mono", dsp->fmt_signed ? "Signed" : "Unsigned", dsp->fmt_bits, dsp->dma_auto ? "Auto" : "Single", dsp->block_size, dsp->freq, dsp->time_const, dsp->speaker); } #endif static void speaker (SB16State *s, int on) { s->speaker = on; /* AUD_enable (s->voice, on); */ } static void control (SB16State *s, int hold) { int dma = s->use_hdma ? s->hdma : s->dma; s->dma_running = hold; ldebug ("hold %d high %d dma %d\n", hold, s->use_hdma, dma); if (hold) { DMA_hold_DREQ (dma); AUD_enable (s->voice, 1); } else { DMA_release_DREQ (dma); AUD_enable (s->voice, 0); } } static void aux_timer (void *opaque) { SB16State *s = opaque; s->can_write = 1; pic_set_irq (s->irq, 1); } #define DMA8_AUTO 1 #define DMA8_HIGH 2 static void dma_cmd8 (SB16State *s, int mask, int dma_len) { s->fmt = AUD_FMT_U8; s->use_hdma = 0; s->fmt_bits = 8; s->fmt_signed = 0; s->fmt_stereo = (s->mixer_regs[0x0e] & 2) != 0; if (-1 == s->time_const) { s->freq = 11025; } else { int tmp = (256 - s->time_const); s->freq = (1000000 + (tmp / 2)) / tmp; } if (-1 != dma_len) s->block_size = dma_len + 1; s->freq >>= s->fmt_stereo; s->left_till_irq = s->block_size; s->bytes_per_second = (s->freq << s->fmt_stereo); /* s->highspeed = (mask & DMA8_HIGH) != 0; */ s->dma_auto = (mask & DMA8_AUTO) != 0; s->align = (1 << s->fmt_stereo) - 1; ldebug ("freq %d, stereo %d, sign %d, bits %d, " "dma %d, auto %d, fifo %d, high %d\n", s->freq, s->fmt_stereo, s->fmt_signed, s->fmt_bits, s->block_size, s->dma_auto, s->fifo, s->highspeed); if (s->freq) s->voice = AUD_open (s->voice, "sb16", s->freq, 1 << s->fmt_stereo, s->fmt); control (s, 1); speaker (s, 1); } static void dma_cmd (SB16State *s, uint8_t cmd, uint8_t d0, int dma_len) { s->use_hdma = cmd < 0xc0; s->fifo = (cmd >> 1) & 1; s->dma_auto = (cmd >> 2) & 1; s->fmt_signed = (d0 >> 4) & 1; s->fmt_stereo = (d0 >> 5) & 1; switch (cmd >> 4) { case 11: s->fmt_bits = 16; break; case 12: s->fmt_bits = 8; break; } if (-1 != s->time_const) { #if 1 int tmp = 256 - s->time_const; s->freq = (1000000 + (tmp / 2)) / tmp; #else /* s->freq = 1000000 / ((255 - s->time_const) << s->fmt_stereo); */ s->freq = 1000000 / ((255 - s->time_const)); #endif s->time_const = -1; } s->block_size = dma_len + 1; s->block_size <<= (s->fmt_bits == 16); if (!s->dma_auto) /* Miles Sound System ? */ s->block_size <<= s->fmt_stereo; ldebug ("freq %d, stereo %d, sign %d, bits %d, " "dma %d, auto %d, fifo %d, high %d\n", s->freq, s->fmt_stereo, s->fmt_signed, s->fmt_bits, s->block_size, s->dma_auto, s->fifo, s->highspeed); if (16 == s->fmt_bits) { if (s->fmt_signed) { s->fmt = AUD_FMT_S16; } else { s->fmt = AUD_FMT_U16; } } else { if (s->fmt_signed) { s->fmt = AUD_FMT_S8; } else { s->fmt = AUD_FMT_U8; } } s->left_till_irq = s->block_size; s->bytes_per_second = (s->freq << s->fmt_stereo) << (s->fmt_bits == 16); s->highspeed = 0; s->align = (1 << (s->fmt_stereo + (s->fmt_bits == 16))) - 1; if (s->freq) s->voice = AUD_open (s->voice, "sb16", s->freq, 1 << s->fmt_stereo, s->fmt); control (s, 1); speaker (s, 1); } static inline void dsp_out_data (SB16State *s, uint8_t val) { ldebug ("outdata %#x\n", val); if (s->out_data_len < sizeof (s->out_data)) s->out_data[s->out_data_len++] = val; } static inline uint8_t dsp_get_data (SB16State *s) { if (s->in_index) return s->in2_data[--s->in_index]; else { dolog ("buffer underflow\n"); return 0; } } static void command (SB16State *s, uint8_t cmd) { ldebug ("command %#x\n", cmd); if (cmd > 0xaf && cmd < 0xd0) { if (cmd & 8) { dolog ("ADC not yet supported (command %#x)\n", cmd); } switch (cmd >> 4) { case 11: case 12: break; default: dolog ("%#x wrong bits\n", cmd); } s->needed_bytes = 3; } else { switch (cmd) { case 0x03: dsp_out_data (s, 0x10); /* s->csp_param); */ goto warn; case 0x04: s->needed_bytes = 1; goto warn; case 0x05: s->needed_bytes = 2; goto warn; case 0x08: /* __asm__ ("int3"); */ goto warn; case 0x0e: s->needed_bytes = 2; goto warn; case 0x09: dsp_out_data (s, 0xf8); goto warn; case 0x0f: s->needed_bytes = 1; goto warn; case 0x10: s->needed_bytes = 1; goto warn; case 0x14: s->needed_bytes = 2; s->block_size = 0; break; case 0x20: /* Direct ADC, Juice/PL */ dsp_out_data (s, 0xff); goto warn; case 0x35: dolog ("MIDI command(0x35) not implemented\n"); break; case 0x40: s->freq = -1; s->time_const = -1; s->needed_bytes = 1; break; case 0x41: s->freq = -1; s->time_const = -1; s->needed_bytes = 2; break; case 0x42: s->freq = -1; s->time_const = -1; s->needed_bytes = 2; goto warn; case 0x45: dsp_out_data (s, 0xaa); goto warn; case 0x47: /* Continue Auto-Initialize DMA 16bit */ break; case 0x48: s->needed_bytes = 2; break; case 0x80: s->needed_bytes = 2; break; case 0x90: case 0x91: dma_cmd8 (s, ((cmd & 1) == 0) | DMA8_HIGH, -1); break; case 0xd0: /* halt DMA operation. 8bit */ control (s, 0); break; case 0xd1: /* speaker on */ speaker (s, 1); break; case 0xd3: /* speaker off */ speaker (s, 0); break; case 0xd4: /* continue DMA operation. 8bit */ control (s, 1); break; case 0xd5: /* halt DMA operation. 16bit */ control (s, 0); break; case 0xd6: /* continue DMA operation. 16bit */ control (s, 1); break; case 0xd9: /* exit auto-init DMA after this block. 16bit */ s->dma_auto = 0; break; case 0xda: /* exit auto-init DMA after this block. 8bit */ s->dma_auto = 0; break; case 0xe0: s->needed_bytes = 1; goto warn; case 0xe1: dsp_out_data (s, s->ver & 0xff); dsp_out_data (s, s->ver >> 8); break; case 0xe2: s->needed_bytes = 1; goto warn; case 0xe3: { int i; for (i = sizeof (e3) - 1; i >= 0; --i) dsp_out_data (s, e3[i]); } break; case 0xe4: /* write test reg */ s->needed_bytes = 1; break; case 0xe7: dolog ("Attempt to probe for ESS (0xe7)?\n"); return; case 0xe8: /* read test reg */ dsp_out_data (s, s->test_reg); break; case 0xf2: case 0xf3: dsp_out_data (s, 0xaa); s->mixer_regs[0x82] |= (cmd == 0xf2) ? 1 : 2; pic_set_irq (s->irq, 1); break; case 0xf9: s->needed_bytes = 1; goto warn; case 0xfa: dsp_out_data (s, 0); goto warn; case 0xfc: /* FIXME */ dsp_out_data (s, 0); goto warn; default: dolog ("unrecognized command %#x\n", cmd); return; } } s->cmd = cmd; if (!s->needed_bytes) ldebug ("\n"); return; warn: dolog ("warning: command %#x,%d is not trully understood yet\n", cmd, s->needed_bytes); s->cmd = cmd; return; } static uint16_t dsp_get_lohi (SB16State *s) { uint8_t hi = dsp_get_data (s); uint8_t lo = dsp_get_data (s); return (hi << 8) | lo; } static uint16_t dsp_get_hilo (SB16State *s) { uint8_t lo = dsp_get_data (s); uint8_t hi = dsp_get_data (s); return (hi << 8) | lo; } static void complete (SB16State *s) { int d0, d1, d2; ldebug ("complete command %#x, in_index %d, needed_bytes %d\n", s->cmd, s->in_index, s->needed_bytes); if (s->cmd > 0xaf && s->cmd < 0xd0) { d2 = dsp_get_data (s); d1 = dsp_get_data (s); d0 = dsp_get_data (s); if (s->cmd & 8) { dolog ("ADC params cmd = %#x d0 = %d, d1 = %d, d2 = %d\n", s->cmd, d0, d1, d2); } else { ldebug ("cmd = %#x d0 = %d, d1 = %d, d2 = %d\n", s->cmd, d0, d1, d2); dma_cmd (s, s->cmd, d0, d1 + (d2 << 8)); } } else { switch (s->cmd) { case 0x04: s->csp_mode = dsp_get_data (s); s->csp_reg83r = 0; s->csp_reg83w = 0; ldebug ("CSP command 0x04: mode=%#x\n", s->csp_mode); break; case 0x05: s->csp_param = dsp_get_data (s); s->csp_value = dsp_get_data (s); ldebug ("CSP command 0x05: param=%#x value=%#x\n", s->csp_param, s->csp_value); break; case 0x0e: d0 = dsp_get_data (s); d1 = dsp_get_data (s); ldebug ("write CSP register %d <- %#x\n", d1, d0); if (d1 == 0x83) { ldebug ("0x83[%d] <- %#x\n", s->csp_reg83r, d0); s->csp_reg83[s->csp_reg83r % 4] = d0; s->csp_reg83r += 1; } else s->csp_regs[d1] = d0; break; case 0x0f: d0 = dsp_get_data (s); ldebug ("read CSP register %#x -> %#x, mode=%#x\n", d0, s->csp_regs[d0], s->csp_mode); if (d0 == 0x83) { ldebug ("0x83[%d] -> %#x\n", s->csp_reg83w, s->csp_reg83[s->csp_reg83w % 4]); dsp_out_data (s, s->csp_reg83[s->csp_reg83w % 4]); s->csp_reg83w += 1; } else dsp_out_data (s, s->csp_regs[d0]); break; case 0x10: d0 = dsp_get_data (s); dolog ("cmd 0x10 d0=%#x\n", d0); break; case 0x14: dma_cmd8 (s, 0, dsp_get_lohi (s)); /* s->can_write = 0; */ /* qemu_mod_timer (s->aux_ts, qemu_get_clock (vm_clock) + (ticks_per_sec * 320) / 1000000); */ break; case 0x40: s->time_const = dsp_get_data (s); ldebug ("set time const %d\n", s->time_const); break; case 0x42: /* FT2 sets output freq with this, go figure */ dolog ("cmd 0x42 might not do what it think it should\n"); case 0x41: s->freq = dsp_get_hilo (s); ldebug ("set freq %d\n", s->freq); break; case 0x48: s->block_size = dsp_get_lohi (s); /* s->highspeed = 1; */ ldebug ("set dma block len %d\n", s->block_size); break; case 0x80: { int samples, bytes; int64_t ticks; if (-1 == s->freq) s->freq = 11025; samples = dsp_get_lohi (s); bytes = samples << s->fmt_stereo << (s->fmt_bits == 16); ticks = bytes ? (ticks_per_sec / (s->freq / bytes)) : 0; if (!bytes || ticks < ticks_per_sec / 1024) pic_set_irq (s->irq, 1); else qemu_mod_timer (s->aux_ts, qemu_get_clock (vm_clock) + ticks); ldebug ("mix silence %d %d %lld\n", samples, bytes, ticks); } break; case 0xe0: d0 = dsp_get_data (s); s->out_data_len = 0; ldebug ("E0 data = %#x\n", d0); dsp_out_data(s, ~d0); break; case 0xe2: d0 = dsp_get_data (s); dolog ("E2 = %#x\n", d0); break; case 0xe4: s->test_reg = dsp_get_data (s); break; case 0xf9: d0 = dsp_get_data (s); ldebug ("command 0xf9 with %#x\n", d0); switch (d0) { case 0x0e: dsp_out_data (s, 0xff); break; case 0x0f: dsp_out_data (s, 0x07); break; case 0x37: dsp_out_data (s, 0x38); break; default: dsp_out_data (s, 0x00); break; } break; default: dolog ("complete: unrecognized command %#x\n", s->cmd); return; } } ldebug ("\n"); s->cmd = -1; return; } static void reset (SB16State *s) { pic_set_irq (s->irq, 0); if (s->dma_auto) { pic_set_irq (s->irq, 1); pic_set_irq (s->irq, 0); } s->mixer_regs[0x82] = 0; s->dma_auto = 0; s->in_index = 0; s->out_data_len = 0; s->left_till_irq = 0; s->needed_bytes = 0; s->block_size = -1; s->nzero = 0; s->highspeed = 0; s->v2x6 = 0; dsp_out_data(s, 0xaa); speaker (s, 0); control (s, 0); } static IO_WRITE_PROTO (dsp_write) { SB16State *s = opaque; int iport; iport = nport - s->port; ldebug ("write %#x <- %#x\n", nport, val); switch (iport) { case 0x06: switch (val) { case 0x00: if (s->v2x6 == 1) { if (0 && s->highspeed) { s->highspeed = 0; pic_set_irq (s->irq, 0); control (s, 0); } else reset (s); } s->v2x6 = 0; break; case 0x01: case 0x03: /* FreeBSD kludge */ s->v2x6 = 1; break; case 0xc6: s->v2x6 = 0; /* Prince of Persia, csp.sys, diagnose.exe */ break; case 0xb8: /* Panic */ reset (s); break; case 0x39: dsp_out_data (s, 0x38); reset (s); s->v2x6 = 0x39; break; default: s->v2x6 = val; break; } break; case 0x0c: /* write data or command | write status */ /* if (s->highspeed) */ /* break; */ if (0 == s->needed_bytes) { command (s, val); #if 0 if (0 == s->needed_bytes) { log_dsp (s); } #endif } else { if (s->in_index == sizeof (s->in2_data)) { dolog ("in data overrun\n"); } else { s->in2_data[s->in_index++] = val; if (s->in_index == s->needed_bytes) { s->needed_bytes = 0; complete (s); #if 0 log_dsp (s); #endif } } } break; default: ldebug ("(nport=%#x, val=%#x)\n", nport, val); break; } } static IO_READ_PROTO (dsp_read) { SB16State *s = opaque; int iport, retval, ack = 0; iport = nport - s->port; switch (iport) { case 0x06: /* reset */ retval = 0xff; break; case 0x0a: /* read data */ if (s->out_data_len) { retval = s->out_data[--s->out_data_len]; s->last_read_byte = retval; } else { dolog ("empty output buffer\n"); retval = s->last_read_byte; /* goto error; */ } break; case 0x0c: /* 0 can write */ retval = s->can_write ? 0 : 0x80; break; case 0x0d: /* timer interrupt clear */ /* dolog ("timer interrupt clear\n"); */ retval = 0; break; case 0x0e: /* data available status | irq 8 ack */ retval = (!s->out_data_len || s->highspeed) ? 0 : 0x80; if (s->mixer_regs[0x82] & 1) { ack = 1; s->mixer_regs[0x82] &= 1; pic_set_irq (s->irq, 0); } break; case 0x0f: /* irq 16 ack */ retval = 0xff; if (s->mixer_regs[0x82] & 2) { ack = 1; s->mixer_regs[0x82] &= 2; pic_set_irq (s->irq, 0); } break; default: goto error; } if (!ack) ldebug ("read %#x -> %#x\n", nport, retval); return retval; error: dolog ("WARNING dsp_read %#x error\n", nport); return 0xff; } static void reset_mixer (SB16State *s) { int i; memset (s->mixer_regs, 0xff, 0x7f); memset (s->mixer_regs + 0x83, 0xff, sizeof (s->mixer_regs) - 0x83); s->mixer_regs[0x02] = 4; /* master volume 3bits */ s->mixer_regs[0x06] = 4; /* MIDI volume 3bits */ s->mixer_regs[0x08] = 0; /* CD volume 3bits */ s->mixer_regs[0x0a] = 0; /* voice volume 2bits */ /* d5=input filt, d3=lowpass filt, d1,d2=input source */ s->mixer_regs[0x0c] = 0; /* d5=output filt, d1=stereo switch */ s->mixer_regs[0x0e] = 0; /* voice volume L d5,d7, R d1,d3 */ s->mixer_regs[0x04] = (4 << 5) | (4 << 1); /* master ... */ s->mixer_regs[0x22] = (4 << 5) | (4 << 1); /* MIDI ... */ s->mixer_regs[0x26] = (4 << 5) | (4 << 1); for (i = 0x30; i < 0x48; i++) { s->mixer_regs[i] = 0x20; } } static IO_WRITE_PROTO(mixer_write_indexb) { SB16State *s = opaque; s->mixer_nreg = val; } static IO_WRITE_PROTO(mixer_write_datab) { SB16State *s = opaque; ldebug ("mixer_write [%#x] <- %#x\n", s->mixer_nreg, val); if (s->mixer_nreg > sizeof (s->mixer_regs)) return; switch (s->mixer_nreg) { case 0x00: reset_mixer (s); break; case 0x80: { int irq = irq_of_magic (val); ldebug ("setting irq to %d (val=%#x)\n", irq, val); if (irq > 0) s->irq = irq; } break; case 0x81: { int dma, hdma; dma = lsbindex (val & 0xf); hdma = lsbindex (val & 0xf0); dolog ("attempt to set DMA register 8bit %d, 16bit %d (val=%#x)\n", dma, hdma, val); #if 0 s->dma = dma; s->hdma = hdma; #endif } break; case 0x82: dolog ("attempt to write into IRQ status register (val=%#x)\n", val); return; default: if (s->mixer_nreg >= 0x80) dolog ("attempt to write mixer[%#x] <- %#x\n", s->mixer_nreg, val); break; } s->mixer_regs[s->mixer_nreg] = val; } static IO_WRITE_PROTO(mixer_write_indexw) { mixer_write_indexb (opaque, nport, val & 0xff); mixer_write_datab (opaque, nport, (val >> 8) & 0xff); } static IO_READ_PROTO(mixer_read) { SB16State *s = opaque; ldebug ("mixer_read[%#x] -> %#x\n", s->mixer_nreg, s->mixer_regs[s->mixer_nreg]); return s->mixer_regs[s->mixer_nreg]; } static int write_audio (SB16State *s, int nchan, int dma_pos, int dma_len, int len) { int temp, net; uint8_t tmpbuf[4096]; temp = len; net = 0; while (temp) { int left = dma_len - dma_pos; int to_copy, copied; to_copy = audio_MIN (temp, left); if (to_copy > sizeof(tmpbuf)) to_copy = sizeof(tmpbuf); copied = DMA_read_memory (nchan, tmpbuf, dma_pos, to_copy); copied = AUD_write (s->voice, tmpbuf, copied); temp -= copied; dma_pos = (dma_pos + copied) % dma_len; net += copied; if (!copied) break; } return net; } static int SB_read_DMA (void *opaque, int nchan, int dma_pos, int dma_len) { SB16State *s = opaque; int free, rfree, till, copy, written, elapsed; if (s->left_till_irq < 0) { s->left_till_irq = s->block_size; } elapsed = AUD_calc_elapsed (s->voice); free = elapsed;/* AUD_get_free (s->voice); */ rfree = free; free = audio_MIN (free, elapsed) & ~s->align; if ((free <= 0) || !dma_len) { return dma_pos; } copy = free; till = s->left_till_irq; #ifdef DEBUG_SB16_MOST dolog ("pos:%06d free:%d,%d till:%d len:%d\n", dma_pos, free, AUD_get_free (s->voice), till, dma_len); #endif if (till <= copy) { if (0 == s->dma_auto) { copy = till; } } written = write_audio (s, nchan, dma_pos, dma_len, copy); dma_pos = (dma_pos + written) % dma_len; s->left_till_irq -= written; if (s->left_till_irq <= 0) { s->mixer_regs[0x82] |= (nchan & 4) ? 2 : 1; pic_set_irq (s->irq, 1); if (0 == s->dma_auto) { control (s, 0); speaker (s, 0); } } #ifdef DEBUG_SB16_MOST ldebug ("pos %5d free %5d size %5d till % 5d copy %5d dma size %5d\n", dma_pos, free, dma_len, s->left_till_irq, copy, s->block_size); #endif while (s->left_till_irq <= 0) { s->left_till_irq = s->block_size + s->left_till_irq; } AUD_adjust (s->voice, written); return dma_pos; } void SB_timer (void *opaque) { SB16State *s = opaque; AUD_run (); qemu_mod_timer (s->ts, qemu_get_clock (vm_clock) + 1); } static void SB_save (QEMUFile *f, void *opaque) { SB16State *s = opaque; qemu_put_be32s (f, &s->irq); qemu_put_be32s (f, &s->dma); qemu_put_be32s (f, &s->hdma); qemu_put_be32s (f, &s->port); qemu_put_be32s (f, &s->ver); qemu_put_be32s (f, &s->in_index); qemu_put_be32s (f, &s->out_data_len); qemu_put_be32s (f, &s->fmt_stereo); qemu_put_be32s (f, &s->fmt_signed); qemu_put_be32s (f, &s->fmt_bits); qemu_put_be32s (f, &s->fmt); qemu_put_be32s (f, &s->dma_auto); qemu_put_be32s (f, &s->block_size); qemu_put_be32s (f, &s->fifo); qemu_put_be32s (f, &s->freq); qemu_put_be32s (f, &s->time_const); qemu_put_be32s (f, &s->speaker); qemu_put_be32s (f, &s->needed_bytes); qemu_put_be32s (f, &s->cmd); qemu_put_be32s (f, &s->use_hdma); qemu_put_be32s (f, &s->highspeed); qemu_put_be32s (f, &s->can_write); qemu_put_be32s (f, &s->v2x6); qemu_put_8s (f, &s->csp_param); qemu_put_8s (f, &s->csp_value); qemu_put_8s (f, &s->csp_mode); qemu_put_8s (f, &s->csp_param); qemu_put_buffer (f, s->csp_regs, 256); qemu_put_8s (f, &s->csp_index); qemu_put_buffer (f, s->csp_reg83, 4); qemu_put_be32s (f, &s->csp_reg83r); qemu_put_be32s (f, &s->csp_reg83w); qemu_put_buffer (f, s->in2_data, sizeof (s->in2_data)); qemu_put_buffer (f, s->out_data, sizeof (s->out_data)); qemu_put_8s (f, &s->test_reg); qemu_put_8s (f, &s->last_read_byte); qemu_put_be32s (f, &s->nzero); qemu_put_be32s (f, &s->left_till_irq); qemu_put_be32s (f, &s->dma_running); qemu_put_be32s (f, &s->bytes_per_second); qemu_put_be32s (f, &s->align); qemu_put_be32s (f, &s->mixer_nreg); qemu_put_buffer (f, s->mixer_regs, 256); } static int SB_load (QEMUFile *f, void *opaque, int version_id) { SB16State *s = opaque; if (version_id != 1) return -EINVAL; qemu_get_be32s (f, &s->irq); qemu_get_be32s (f, &s->dma); qemu_get_be32s (f, &s->hdma); qemu_get_be32s (f, &s->port); qemu_get_be32s (f, &s->ver); qemu_get_be32s (f, &s->in_index); qemu_get_be32s (f, &s->out_data_len); qemu_get_be32s (f, &s->fmt_stereo); qemu_get_be32s (f, &s->fmt_signed); qemu_get_be32s (f, &s->fmt_bits); qemu_get_be32s (f, &s->fmt); qemu_get_be32s (f, &s->dma_auto); qemu_get_be32s (f, &s->block_size); qemu_get_be32s (f, &s->fifo); qemu_get_be32s (f, &s->freq); qemu_get_be32s (f, &s->time_const); qemu_get_be32s (f, &s->speaker); qemu_get_be32s (f, &s->needed_bytes); qemu_get_be32s (f, &s->cmd); qemu_get_be32s (f, &s->use_hdma); qemu_get_be32s (f, &s->highspeed); qemu_get_be32s (f, &s->can_write); qemu_get_be32s (f, &s->v2x6); qemu_get_8s (f, &s->csp_param); qemu_get_8s (f, &s->csp_value); qemu_get_8s (f, &s->csp_mode); qemu_get_8s (f, &s->csp_param); qemu_get_buffer (f, s->csp_regs, 256); qemu_get_8s (f, &s->csp_index); qemu_get_buffer (f, s->csp_reg83, 4); qemu_get_be32s (f, &s->csp_reg83r); qemu_get_be32s (f, &s->csp_reg83w); qemu_get_buffer (f, s->in2_data, sizeof (s->in2_data)); qemu_get_buffer (f, s->out_data, sizeof (s->out_data)); qemu_get_8s (f, &s->test_reg); qemu_get_8s (f, &s->last_read_byte); qemu_get_be32s (f, &s->nzero); qemu_get_be32s (f, &s->left_till_irq); qemu_get_be32s (f, &s->dma_running); qemu_get_be32s (f, &s->bytes_per_second); qemu_get_be32s (f, &s->align); qemu_get_be32s (f, &s->mixer_nreg); qemu_get_buffer (f, s->mixer_regs, 256); if (s->voice) { AUD_close (s->voice); s->voice = NULL; } if (s->dma_running) { if (s->freq) s->voice = AUD_open (s->voice, "sb16", s->freq, 1 << s->fmt_stereo, s->fmt); control (s, 1); speaker (s, s->speaker); } return 0; } void SB16_init (void) { SB16State *s = &dsp; int i; static const uint8_t dsp_write_ports[] = {0x6, 0xc}; static const uint8_t dsp_read_ports[] = {0x6, 0xa, 0xc, 0xd, 0xe, 0xf}; s->ts = qemu_new_timer (vm_clock, SB_timer, s); if (!s->ts) return; s->irq = conf.irq; s->dma = conf.dma; s->hdma = conf.hdma; s->port = conf.port; s->ver = conf.ver_lo | (conf.ver_hi << 8); s->mixer_regs[0x80] = magic_of_irq (s->irq); s->mixer_regs[0x81] = (1 << s->dma) | (1 << s->hdma); s->mixer_regs[0x82] = 2 << 5; s->csp_regs[5] = 1; s->csp_regs[9] = 0xf8; reset_mixer (s); s->aux_ts = qemu_new_timer (vm_clock, aux_timer, s); if (!s->aux_ts) return; for (i = 0; i < LENOFA (dsp_write_ports); i++) { register_ioport_write (s->port + dsp_write_ports[i], 1, 1, dsp_write, s); } for (i = 0; i < LENOFA (dsp_read_ports); i++) { register_ioport_read (s->port + dsp_read_ports[i], 1, 1, dsp_read, s); } register_ioport_write (s->port + 0x4, 1, 1, mixer_write_indexb, s); register_ioport_write (s->port + 0x4, 1, 2, mixer_write_indexw, s); register_ioport_read (s->port + 0x5, 1, 1, mixer_read, s); register_ioport_write (s->port + 0x5, 1, 1, mixer_write_datab, s); DMA_register_channel (s->hdma, SB_read_DMA, s); DMA_register_channel (s->dma, SB_read_DMA, s); s->can_write = 1; qemu_mod_timer (s->ts, qemu_get_clock (vm_clock) + 1); register_savevm ("sb16", 0, 1, SB_save, SB_load, s); }