initial import

git-svn-id: file:///home/notaz/opt/svn/PicoDrive@2 be3aeb3a-fb24-0410-a615-afba39da0efa

Pico/sound/sn76496.c

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+/***************************************************************************
+
+  sn76496.c
+
+  Routines to emulate the Texas Instruments SN76489 / SN76496 programmable
+  tone /noise generator. Also known as (or at least compatible with) TMS9919.
+
+  Noise emulation is not accurate due to lack of documentation. The noise
+  generator uses a shift register with a XOR-feedback network, but the exact
+  layout is unknown. It can be set for either period or white noise; again,
+  the details are unknown.
+
+  28/03/2005 : Sebastien Chevalier
+  Update th SN76496Write func, according to SN76489 doc found on SMSPower.
+   - On write with 0x80 set to 0, when LastRegister is other then TONE,
+   the function is similar than update with 0x80 set to 1
+***************************************************************************/
+
+#ifndef __GNUC__
+#pragma warning (disable:4244)
+#endif
+
+#include "sn76496.h"
+
+#define MAX_OUTPUT 0x47ff // was 0x7fff
+
+#define STEP 0x10000
+
+
+/* Formulas for noise generator */
+/* bit0 = output */
+
+/* noise feedback for white noise mode (verified on real SN76489 by John Kortink) */
+#define FB_WNOISE 0x14002	/* (16bits) bit16 = bit0(out) ^ bit2 ^ bit15 */
+
+/* noise feedback for periodic noise mode */
+//#define FB_PNOISE 0x10000 /* 16bit rorate */
+#define FB_PNOISE 0x08000   /* JH 981127 - fixes Do Run Run */
+
+/*
+0x08000 is definitely wrong. The Master System conversion of Marble Madness
+uses periodic noise as a baseline. With a 15-bit rotate, the bassline is
+out of tune.
+The 16-bit rotate has been confirmed against a real PAL Sega Master System 2.
+Hope that helps the System E stuff, more news on the PSG as and when!
+*/
+
+/* noise generator start preset (for periodic noise) */
+#define NG_PRESET 0x0f35
+
+
+struct SN76496
+{
+	//sound_stream * Channel;
+	int SampleRate;
+	unsigned int UpdateStep;
+	int VolTable[16];	/* volume table         */
+	int Register[8];	/* registers */
+	int LastRegister;	/* last register written */
+	int Volume[4];		/* volume of voice 0-2 and noise */
+	unsigned int RNG;		/* noise generator      */
+	int NoiseFB;		/* noise feedback mask */
+	int Period[4];
+	int Count[4];
+	int Output[4];
+	int pad[1];
+};
+
+static struct SN76496 ono_sn; // one and only SN76496
+int *sn76496_regs;
+
+//static
+void SN76496Write(int data)
+{
+	struct SN76496 *R = &ono_sn;
+	int n;
+
+
+	/* update the output buffer before changing the registers */
+	//stream_update(R->Channel,0);
+
+	if (data & 0x80)
+	{
+		int r = (data & 0x70) >> 4;
+		int c = r/2;
+
+		R->LastRegister = r;
+		R->Register[r] = (R->Register[r] & 0x3f0) | (data & 0x0f);
+		switch (r)
+		{
+			case 0:	/* tone 0 : frequency */
+			case 2:	/* tone 1 : frequency */
+			case 4:	/* tone 2 : frequency */
+				R->Period[c] = R->UpdateStep * R->Register[r];
+				if (R->Period[c] == 0) R->Period[c] = R->UpdateStep;
+				if (r == 4)
+				{
+					/* update noise shift frequency */
+					if ((R->Register[6] & 0x03) == 0x03)
+						R->Period[3] = 2 * R->Period[2];
+				}
+				break;
+			case 1:	/* tone 0 : volume */
+			case 3:	/* tone 1 : volume */
+			case 5:	/* tone 2 : volume */
+			case 7:	/* noise  : volume */
+				R->Volume[c] = R->VolTable[data & 0x0f];
+				break;
+			case 6:	/* noise  : frequency, mode */
+				{
+					int n = R->Register[6];
+					R->NoiseFB = (n & 4) ? FB_WNOISE : FB_PNOISE;
+					n &= 3;
+					/* N/512,N/1024,N/2048,Tone #3 output */
+					R->Period[3] = ((n&3) == 3) ? 2 * R->Period[2] : (R->UpdateStep << (5+(n&3)));
+
+					/* reset noise shifter */
+					R->RNG = NG_PRESET;
+					R->Output[3] = R->RNG & 1;
+				}
+				break;
+		}
+	}
+	else
+	{
+		int r = R->LastRegister;
+		int c = r/2;
+
+		switch (r)
+		{
+			case 0:	/* tone 0 : frequency */
+			case 2:	/* tone 1 : frequency */
+			case 4:	/* tone 2 : frequency */
+				R->Register[r] = (R->Register[r] & 0x0f) | ((data & 0x3f) << 4);
+				R->Period[c] = R->UpdateStep * R->Register[r];
+				if (R->Period[c] == 0) R->Period[c] = R->UpdateStep;
+				if (r == 4)
+				{
+					/* update noise shift frequency */
+					if ((R->Register[6] & 0x03) == 0x03)
+						R->Period[3] = 2 * R->Period[2];
+				}
+				break;
+			case 1:	/* tone 0 : volume */
+			case 3:	/* tone 1 : volume */
+			case 5:	/* tone 2 : volume */
+			case 7:	/* noise  : volume */
+				R->Volume[c] = R->VolTable[data & 0x0f];
+				R->Register[r] = (R->Register[r] & 0x3f0) | (data & 0x0f);
+				break;
+			case 6:	/* noise  : frequency, mode */
+				{
+					R->Register[r] = (R->Register[r] & 0x3f0) | (data & 0x0f);
+					n = R->Register[6];
+					R->NoiseFB = (n & 4) ? FB_WNOISE : FB_PNOISE;
+					n &= 3;
+					/* N/512,N/1024,N/2048,Tone #3 output */
+					R->Period[3] = ((n&3) == 3) ? 2 * R->Period[2] : (R->UpdateStep << (5+(n&3)));
+
+					/* reset noise shifter */
+					R->RNG = NG_PRESET;
+					R->Output[3] = R->RNG & 1;
+				}
+				break;
+		}
+	}
+}
+
+/*
+WRITE8_HANDLER( SN76496_0_w ) {	SN76496Write(0,data); }
+WRITE8_HANDLER( SN76496_1_w ) {	SN76496Write(1,data); }
+WRITE8_HANDLER( SN76496_2_w ) {	SN76496Write(2,data); }
+WRITE8_HANDLER( SN76496_3_w ) {	SN76496Write(3,data); }
+WRITE8_HANDLER( SN76496_4_w ) {	SN76496Write(4,data); }
+*/
+
+//static
+void SN76496Update(short *buffer,int length,int stereo)
+{
+	int i;
+	struct SN76496 *R = &ono_sn;
+
+	/* If the volume is 0, increase the counter */
+	for (i = 0;i < 4;i++)
+	{
+		if (R->Volume[i] == 0)
+		{
+			/* note that I do count += length, NOT count = length + 1. You might think */
+			/* it's the same since the volume is 0, but doing the latter could cause */
+			/* interferencies when the program is rapidly modulating the volume. */
+			if (R->Count[i] <= length*STEP) R->Count[i] += length*STEP;
+		}
+	}
+
+	while (length > 0)
+	{
+		int vol[4];
+		unsigned int out;
+		int left;
+
+
+		/* vol[] keeps track of how long each square wave stays */
+		/* in the 1 position during the sample period. */
+		vol[0] = vol[1] = vol[2] = vol[3] = 0;
+
+		for (i = 0;i < 3;i++)
+		{
+			if (R->Output[i]) vol[i] += R->Count[i];
+			R->Count[i] -= STEP;
+			/* Period[i] is the half period of the square wave. Here, in each */
+			/* loop I add Period[i] twice, so that at the end of the loop the */
+			/* square wave is in the same status (0 or 1) it was at the start. */
+			/* vol[i] is also incremented by Period[i], since the wave has been 1 */
+			/* exactly half of the time, regardless of the initial position. */
+			/* If we exit the loop in the middle, Output[i] has to be inverted */
+			/* and vol[i] incremented only if the exit status of the square */
+			/* wave is 1. */
+			while (R->Count[i] <= 0)
+			{
+				R->Count[i] += R->Period[i];
+				if (R->Count[i] > 0)
+				{
+					R->Output[i] ^= 1;
+					if (R->Output[i]) vol[i] += R->Period[i];
+					break;
+				}
+				R->Count[i] += R->Period[i];
+				vol[i] += R->Period[i];
+			}
+			if (R->Output[i]) vol[i] -= R->Count[i];
+		}
+
+		left = STEP;
+		do
+		{
+			int nextevent;
+
+			if (R->Count[3] < left) nextevent = R->Count[3];
+			else nextevent = left;
+
+			if (R->Output[3]) vol[3] += R->Count[3];
+			R->Count[3] -= nextevent;
+			if (R->Count[3] <= 0)
+			{
+				if (R->RNG & 1) R->RNG ^= R->NoiseFB;
+				R->RNG >>= 1;
+				R->Output[3] = R->RNG & 1;
+				R->Count[3] += R->Period[3];
+				if (R->Output[3]) vol[3] += R->Period[3];
+			}
+			if (R->Output[3]) vol[3] -= R->Count[3];
+
+			left -= nextevent;
+		} while (left > 0);
+
+		out = vol[0] * R->Volume[0] + vol[1] * R->Volume[1] +
+				vol[2] * R->Volume[2] + vol[3] * R->Volume[3];
+
+		if (out > MAX_OUTPUT * STEP) out = MAX_OUTPUT * STEP;
+
+		out /= STEP; // will be optimized to shift
+		if(stereo) {
+			// only left channel for stereo (will be copied to right by ym2612 mixing code)
+			*buffer += out;
+			buffer+=2;
+		} else
+			*buffer++ += out;
+
+		length--;
+	}
+}
+
+
+static void SN76496_set_clock(struct SN76496 *R,int clock)
+{
+
+	/* the base clock for the tone generators is the chip clock divided by 16; */
+	/* for the noise generator, it is clock / 256. */
+	/* Here we calculate the number of steps which happen during one sample */
+	/* at the given sample rate. No. of events = sample rate / (clock/16). */
+	/* STEP is a multiplier used to turn the fraction into a fixed point */
+	/* number. */
+	R->UpdateStep = ((double)STEP * R->SampleRate * 16) / clock;
+}
+
+
+static void SN76496_set_gain(struct SN76496 *R,int gain)
+{
+	int i;
+	double out;
+
+
+	gain &= 0xff;
+
+	/* increase max output basing on gain (0.2 dB per step) */
+	out = MAX_OUTPUT / 3;
+	while (gain-- > 0)
+		out *= 1.023292992;	/* = (10 ^ (0.2/20)) */
+
+	/* build volume table (2dB per step) */
+	for (i = 0;i < 15;i++)
+	{
+		/* limit volume to avoid clipping */
+		if (out > MAX_OUTPUT / 3) R->VolTable[i] = MAX_OUTPUT / 3;
+		else R->VolTable[i] = out;
+
+		out /= 1.258925412;	/* = 10 ^ (2/20) = 2dB */
+	}
+	R->VolTable[15] = 0;
+}
+
+
+//static
+int SN76496_init(int clock,int sample_rate)
+{
+	struct SN76496 *R = &ono_sn;
+	int i;
+
+	//R->Channel = stream_create(0,1, sample_rate,R,SN76496Update);
+	sn76496_regs = R->Register;
+
+	R->SampleRate = sample_rate;
+	SN76496_set_clock(R,clock);
+
+	for (i = 0;i < 4;i++) R->Volume[i] = 0;
+
+	R->LastRegister = 0;
+	for (i = 0;i < 8;i+=2)
+	{
+		R->Register[i] = 0;
+		R->Register[i + 1] = 0x0f;	/* volume = 0 */
+	}
+
+	for (i = 0;i < 4;i++)
+	{
+		R->Output[i] = 0;
+		R->Period[i] = R->Count[i] = R->UpdateStep;
+	}
+	R->RNG = NG_PRESET;
+	R->Output[3] = R->RNG & 1;
+
+	// added
+	SN76496_set_gain(R, 0);
+
+	return 0;
+}
+