snd_dos.c */ #include "quakedef.h" #include "dosisms.h" int BLASTER_GetDMAPos(void); /* =============================================================================== GUS SUPPORT =============================================================================== */ qboolean GUS_Init (void); int GUS_GetDMAPos (void); void GUS_Shutdown (void); /* =============================================================================== BLASTER SUPPORT =============================================================================== */ short *dma_buffer=0; static int dma_size; static int dma; static int dsp_port; static int irq; static int low_dma; static int high_dma; static int mixer_port; static int mpu401_port; int dsp_version; int dsp_minor_version; int timeconstant=-1; void PrintBits (byte b) { int i; char str[9]; for (i=0 ; i<8 ; i++) str[i] = '0' + ((b & (1<<(7-i))) > 0); str[8] = 0; Con_Printf ("%s (%i)", str, b); } void SB_Info_f(void) { Con_Printf ("BLASTER=%s\n", getenv("BLASTER")); Con_Printf("dsp version=%d.%d\n", dsp_version, dsp_minor_version); Con_Printf("dma=%d\n", dma); if (timeconstant != -1) Con_Printf("timeconstant=%d\n", timeconstant); Con_Printf("dma position:%i\n", BLASTER_GetDMAPos ()); } // ======================================================================= // Interprets BLASTER variable // ======================================================================= int GetBLASTER(void) { char *BLASTER; char *param; BLASTER = getenv("BLASTER"); if (!BLASTER) return 0; param = strchr(BLASTER, 'A'); if (!param) param = strchr(BLASTER, 'a'); if (!param) return 0; sscanf(param+1, "%x", &dsp_port); param = strchr(BLASTER, 'I'); if (!param) param = strchr(BLASTER, 'i'); if (!param) return 0; sscanf(param+1, "%d", &irq); param = strchr(BLASTER, 'D'); if (!param) param = strchr(BLASTER, 'd'); if (!param) return 0; sscanf(param+1, "%d", &low_dma); param = strchr(BLASTER, 'H'); if (!param) param = strchr(BLASTER, 'h'); if (param) sscanf(param+1, "%d", &high_dma); param = strchr(BLASTER, 'M'); if (!param) param = strchr(BLASTER, 'm'); if (param) sscanf(param+1, "%x", &mixer_port); else mixer_port = dsp_port; param = strchr(BLASTER, 'P'); if (!param) param = strchr(BLASTER, 'p'); if (param) sscanf(param+1, "%x", &mpu401_port); return 1; } // ================================================================== // Resets DSP. Returns 0 on success. // ================================================================== int ResetDSP(void) { volatile int i; dos_outportb(dsp_port + 6, 1); for (i=65536 ; i ; i--) ; dos_outportb(dsp_port + 6, 0); for (i=65536 ; i ; i--) { if (!(dos_inportb(dsp_port + 0xe) & 0x80)) continue; if (dos_inportb(dsp_port + 0xa) == 0xaa) break; } if (i) return 0; else return 1; } int ReadDSP(void) { while (!(dos_inportb(dsp_port+0xe)&0x80)) ; return dos_inportb(dsp_port+0xa); } void WriteDSP(int val) { while ((dos_inportb(dsp_port+0xc)&0x80)) ; dos_outportb(dsp_port+0xc, val); } int ReadMixer(int addr) { dos_outportb(mixer_port+4, addr); return dos_inportb(mixer_port+5); } void WriteMixer(int addr, int val) { dos_outportb(mixer_port+4, addr); dos_outportb(mixer_port+5, val); } int oldmixervalue; /* ================ StartSB ================ */ void StartSB(void) { int i; // version 4.xx startup code if (dsp_version >= 4) { Con_Printf("Version 4 SB startup\n"); WriteDSP(0xd1); // turn on speaker WriteDSP(0x41); WriteDSP(shm->speed>>8); WriteDSP(shm->speed&0xff); WriteDSP(0xb6); // 16-bit output WriteDSP(0x30); // stereo WriteDSP((shm->samples-1) & 0xff); // # of samples - 1 WriteDSP((shm->samples-1) >> 8); } // version 3.xx startup code else if (dsp_version == 3) { Con_Printf("Version 3 SB startup\n"); WriteDSP(0xd1); // turn on speaker oldmixervalue = ReadMixer (0xe); WriteMixer (0xe, oldmixervalue | 0x2);// turn on stereo WriteDSP(0x14); // send one byte WriteDSP(0x0); WriteDSP(0x0); for (i=0 ; i<0x10000 ; i++) dos_inportb(dsp_port+0xe); // ack the dsp timeconstant = 65536-(256000000/(shm->channels*shm->speed)); WriteDSP(0x40); WriteDSP(timeconstant>>8); WriteMixer (0xe, ReadMixer(0xe) | 0x20);// turn off filter WriteDSP(0x48); WriteDSP((shm->samples-1) & 0xff); // # of samples - 1 WriteDSP((shm->samples-1) >> 8); WriteDSP(0x90); // high speed 8 bit stereo } // normal speed mono else { Con_Printf("Version 2 SB startup\n"); WriteDSP(0xd1); // turn on speaker timeconstant = 65536-(256000000/(shm->channels*shm->speed)); WriteDSP(0x40); WriteDSP(timeconstant>>8); WriteDSP(0x48); WriteDSP((shm->samples-1) & 0xff); // # of samples - 1 WriteDSP((shm->samples-1) >> 8); WriteDSP(0x1c); // normal speed 8 bit mono } } static int page_reg[] = { 0x87, 0x83, 0x81, 0x82, 0x8f, 0x8b, 0x89, 0x8a }; static int addr_reg[] = { 0, 2, 4, 6, 0xc0, 0xc4, 0xc8, 0xcc }; static int count_reg[] = { 1, 3, 5, 7, 0xc2, 0xc6, 0xca, 0xce }; static int mode_reg; static int flipflop_reg; static int disable_reg; static int clear_reg; /* ================ StartDMA ================ */ void StartDMA(void) { int mode; int realaddr; realaddr = ptr2real(dma_buffer); // use a high dma channel if specified if (high_dma && dsp_version >= 4) // 8 bit snd can never use 16 bit dma dma = high_dma; else dma = low_dma; Con_Printf ("Using DMA channel %i\n", dma); if (dma > 3) { mode_reg = 0xd6; flipflop_reg = 0xd8; disable_reg = 0xd4; clear_reg = 0xdc; } else { mode_reg = 0xb; flipflop_reg = 0xc; disable_reg = 0xa; clear_reg = 0xe; } dos_outportb(disable_reg, dma|4); // disable channel // set mode- see "undocumented pc", p.876 mode = (1<<6) // single-cycle +(0<<5) // address increment +(1<<4) // auto-init dma +(2<<2) // read +(dma&3); // channel # dos_outportb(mode_reg, mode); // set address // set page dos_outportb(page_reg[dma], realaddr >> 16); if (dma > 3) { // address is in words dos_outportb(flipflop_reg, 0); // prepare to send 16-bit value dos_outportb(addr_reg[dma], (realaddr>>1) & 0xff); dos_outportb(addr_reg[dma], (realaddr>>9) & 0xff); dos_outportb(flipflop_reg, 0); // prepare to send 16-bit value dos_outportb(count_reg[dma], ((dma_size>>1)-1) & 0xff); dos_outportb(count_reg[dma], ((dma_size>>1)-1) >> 8); } else { // address is in bytes dos_outportb(flipflop_reg, 0); // prepare to send 16-bit value dos_outportb(addr_reg[dma], realaddr & 0xff); dos_outportb(addr_reg[dma], (realaddr>>8) & 0xff); dos_outportb(flipflop_reg, 0); // prepare to send 16-bit value dos_outportb(count_reg[dma], (dma_size-1) & 0xff); dos_outportb(count_reg[dma], (dma_size-1) >> 8); } dos_outportb(clear_reg, 0); // clear write mask dos_outportb(disable_reg, dma&~4); } /* ================== BLASTER_Init Returns false if nothing is found. ================== */ qboolean BLASTER_Init(void) { int size; int realaddr; int rc; int p; shm = 0; rc = 0; // // must have a blaster variable set // if (!GetBLASTER()) { Con_NotifyBox ( "The BLASTER environment variable\n" "is not set, sound effects are\n" "disabled. See README.TXT for help.\n" ); return 0; } if (ResetDSP()) { Con_Printf("Could not reset SB"); return 0; } // // get dsp version // WriteDSP(0xe1); dsp_version = ReadDSP(); dsp_minor_version = ReadDSP(); // we need at least v2 for auto-init dma if (dsp_version < 2) { Con_Printf ("Sound blaster must be at least v2.0\n"); return 0; } // allow command line parm to set quality down p = COM_CheckParm ("-dsp"); if (p && p < com_argc - 1) { p = Q_atoi (com_argv[p+1]); if (p < 2 || p > 4) Con_Printf ("-dsp parameter can only be 2, 3, or 4\n"); else if (p > dsp_version) Con_Printf ("Can't -dsp %i on v%i hardware\n", p, dsp_version); else dsp_version = p; } // everyone does 11khz sampling rate unless told otherwise shm = &sn; shm->speed = 11025; rc = COM_CheckParm("-sspeed"); if (rc) shm->speed = Q_atoi(com_argv[rc+1]); // version 4 cards (sb 16) do 16 bit stereo if (dsp_version >= 4) { shm->channels = 2; shm->samplebits = 16; } // version 3 cards (sb pro) do 8 bit stereo else if (dsp_version == 3) { shm->channels = 2; shm->samplebits = 8; } // v2 cards do 8 bit mono else { shm->channels = 1; shm->samplebits = 8; } Cmd_AddCommand("sbinfo", SB_Info_f); size = 4096; // allocate 8k and get a 4k-aligned buffer from it dma_buffer = dos_getmemory(size*2); if (!dma_buffer) { Con_Printf("Couldn't allocate sound dma buffer"); return false; } realaddr = ptr2real(dma_buffer); realaddr = (realaddr + size) & ~(size-1); dma_buffer = (short *) real2ptr(realaddr); dma_size = size; memset(dma_buffer, 0, dma_size); shm->soundalive = true; shm->splitbuffer = false; shm->samples = size/(shm->samplebits/8); shm->samplepos = 0; shm->submission_chunk = 1; shm->buffer = (unsigned char *) dma_buffer; shm->samples = size/(shm->samplebits/8); StartDMA(); StartSB(); return true; } /* ============== BLASTER_GetDMAPos return the current sample position (in mono samples read) inside the recirculating dma buffer, so the mixing code will know how many sample are required to fill it up. =============== */ int BLASTER_GetDMAPos(void) { int count; // this function is called often. acknowledge the transfer completions // all the time so that it loops if (dsp_version >= 4) dos_inportb(dsp_port+0xf); // 16 bit audio else dos_inportb(dsp_port+0xe); // 8 bit audio // clear 16-bit reg flip-flop // load the current dma count register if (dma < 4) { dos_outportb(0xc, 0); count = dos_inportb(dma*2+1); count += dos_inportb(dma*2+1) << 8; if (shm->samplebits == 16) count /= 2; count = shm->samples - (count+1); } else { dos_outportb(0xd8, 0); count = dos_inportb(0xc0+(dma-4)*4+2); count += dos_inportb(0xc0+(dma-4)*4+2) << 8; if (shm->samplebits == 8) count *= 2; count = shm->samples - (count+1); } // Con_Printf("DMA pos = 0x%x\n", count); shm->samplepos = count & (shm->samples-1); return shm->samplepos; } /* ============== BLASTER_Shutdown Reset the sound device for exiting =============== */ void BLASTER_Shutdown(void) { if (dsp_version >= 4) { } else if (dsp_version == 3) { ResetDSP (); // stop high speed mode WriteMixer (0xe, oldmixervalue); // turn stereo off and filter on } else { } WriteDSP(0xd3); // turn off speaker ResetDSP (); dos_outportb(disable_reg, dma|4); // disable dma channel } /* =============================================================================== INTERFACE =============================================================================== */ typedef enum { dma_none, dma_blaster, dma_gus } dmacard_t; dmacard_t dmacard; /* ================== SNDDM_Init Try to find a sound device to mix for. Returns false if nothing is found. Returns true and fills in the "shm" structure with information for the mixer. ================== */ qboolean SNDDMA_Init(void) { if (GUS_Init ()) { dmacard = dma_gus; return true; } if (BLASTER_Init ()) { dmacard = dma_blaster; return true; } dmacard = dma_none; return false; } /* ============== SNDDMA_GetDMAPos return the current sample position (in mono samples, not stereo) inside the recirculating dma buffer, so the mixing code will know how many sample are required to fill it up. =============== */ int SNDDMA_GetDMAPos(void) { switch (dmacard) { case dma_blaster: return BLASTER_GetDMAPos (); case dma_gus: return GUS_GetDMAPos (); case dma_none: break; } return 0; } /* ============== SNDDMA_Shutdown Reset the sound device for exiting =============== */ void SNDDMA_Shutdown(void) { switch (dmacard) { case dma_blaster: BLASTER_Shutdown (); break; case dma_gus: GUS_Shutdown (); break; case dma_none: break; } dmacard = dma_none; return; } /* ============== SNDDMA_Submit Send sound to device if buffer isn't really the dma buffer =============== */ void SNDDMA_Submit(void) { }