From: kub Date: Wed, 24 Jan 2024 20:14:42 +0000 (+0100) Subject: core, some updates for Pico adpcm X-Git-Tag: v2.00~128 X-Git-Url: https://notaz.gp2x.de/cgi-bin/gitweb.cgi?a=commitdiff_plain;h=492c47c4b8413a6c02efe761c8217c190cefffb8;p=picodrive.git core, some updates for Pico adpcm --- diff --git a/pico/pico/xpcm.c b/pico/pico/xpcm.c index 91749bac..7d69b43e 100644 --- a/pico/pico/xpcm.c +++ b/pico/pico/xpcm.c @@ -7,6 +7,17 @@ * See COPYING file in the top-level directory. * * The following ADPCM algorithm was derived from MAME upd7759 driver. + * + * The Pico is using this chip in slave mode. In this mode there are no ROM + * headers, but the first byte sent to the chip is used to start the ADPCM + * engine. This byte is discarded, i.e. not processed by the engine. + * + * Data is fed into the chip through a FIFO. An Interrupt is created if the + * FIFO has been drained below the low water mark. + * + * The Pico has 2 extensions to the standard upd7759 chip: + * - gain control, used to control the volume of the ADPCM output + * - filtering, used to remove (some of) the ADPCM compression artifacts */ #include @@ -42,21 +53,24 @@ static const int step_deltas[16][16] = static const int state_deltas[16] = { -1, -1, 0, 0, 1, 2, 2, 3, -1, -1, 0, 0, 1, 2, 2, 3 }; -s32 stepsamples = (44100LL<<16)/ADPCM_CLOCK; +static s32 stepsamples; // ratio as Q16, host sound rate / chip sample rate static struct xpcm_state { s32 samplepos; // leftover duration for current sample wrt sndrate, Q16 int sample; // current sample - short state; // ADPCM engine state + short state; // ADPCM decoder state short samplegain; // programmable gain char startpin; // value on the !START pin char irqenable; // IRQ enabled? - char portstate; // data stream state + char portstate; // ADPCM stream state short silence; // silence blocks still to be played short rate, nibbles; // ADPCM nibbles still to be played - unsigned char highlow, cache; // nibble selector and cache + unsigned char highlow, cache; // nibble selector and cache + + char filter; // filter selector + s32 x[3], y[3]; // filter history } xpcm; enum { RESET, START, HDR, COUNT }; // portstate @@ -66,15 +80,15 @@ enum { RESET, START, HDR, COUNT }; // portstate #define QB 16 // mantissa bits #define FP(f) (int)((f)*(1<= rate/2) { memset(iir, 0, sizeof(*iir)); return; @@ -95,12 +109,12 @@ static int PicoPicoFilterApply(struct iir2 *iir, int sample) return sample; // NB Butterworth specific! - iir->x[0] = iir->x[1]; iir->x[1] = iir->x[2]; - iir->x[2] = sample * iir->gain; // Qb - iir->y[0] = iir->y[1]; iir->y[1] = iir->y[2]; - iir->y[2] = (iir->x[0] + 2*iir->x[1] + iir->x[2] - + iir->y[0]*iir->a[1] + iir->y[1]*iir->a[0]) >> QB; - return iir->y[2]; + xpcm.x[0] = xpcm.x[1]; xpcm.x[1] = xpcm.x[2]; + xpcm.x[2] = sample * iir->gain; // Qb + xpcm.y[0] = xpcm.y[1]; xpcm.y[1] = xpcm.y[2]; + xpcm.y[2] = (xpcm.x[0] + 2*xpcm.x[1] + xpcm.x[2] + + xpcm.y[0]*iir->a[1] + xpcm.y[1]*iir->a[0]) >> QB; + return xpcm.y[2]; } @@ -131,13 +145,23 @@ PICO_INTERNAL int PicoPicoPCMBusyN(void) PICO_INTERNAL void PicoPicoPCMRerate(void) { + s32 nextstep = ((u64)PicoIn.sndRate<<16)/ADPCM_CLOCK; + + // if the sound rate changes, erase filter history to avoid freak behaviour + if (stepsamples != nextstep) { + memset(xpcm.x, 0, sizeof(xpcm.x)); + memset(xpcm.y, 0, sizeof(xpcm.y)); + } + // output samples per chip clock - stepsamples = ((u64)PicoIn.sndRate<<16)/ADPCM_CLOCK; + stepsamples = nextstep; // compute filter coefficients, cutoff at half the ADPCM sample rate PicoPicoFilterCoeff(&filters[1], 6000/2, PicoIn.sndRate); // 5-6 KHz PicoPicoFilterCoeff(&filters[2], 9000/2, PicoIn.sndRate); // 8-12 KHz PicoPicoFilterCoeff(&filters[3], 15000/2, PicoIn.sndRate); // 14-16 KHz + + PicoPicoPCMFilter(xpcm.filter); } PICO_INTERNAL void PicoPicoPCMGain(int gain) @@ -147,6 +171,13 @@ PICO_INTERNAL void PicoPicoPCMGain(int gain) PICO_INTERNAL void PicoPicoPCMFilter(int index) { + // if the filter changes, erase the history to avoid freak behaviour + if (index != xpcm.filter) { + memset(xpcm.x, 0, sizeof(xpcm.x)); + memset(xpcm.y, 0, sizeof(xpcm.y)); + } + + xpcm.filter = index; filter = filters+index; if (filter->a[0] == 0) filter = NULL; @@ -204,12 +235,13 @@ PICO_INTERNAL void PicoPicoPCMUpdate(short *buffer, int length, int stereo) // loop over FIFO data, generating ADPCM samples while (length > 0 && src < lim) { - if (xpcm.silence > 0) { + // ADPCM state engine + if (xpcm.silence > 0) { // generate silence xpcm.silence --; xpcm.sample = 0; xpcm.samplepos += stepsamples*256; - } else if (xpcm.nibbles > 0) { + } else if (xpcm.nibbles > 0) { // produce samples xpcm.nibbles --; if (xpcm.highlow) @@ -221,7 +253,7 @@ PICO_INTERNAL void PicoPicoPCMUpdate(short *buffer, int length, int stereo) do_sample((xpcm.cache & 0xf0) >> 4); xpcm.samplepos += stepsamples*xpcm.rate; - } else switch (xpcm.portstate) { + } else switch (xpcm.portstate) { // handle stream headers case RESET: xpcm.sample = 0; xpcm.samplepos += length<<16; @@ -301,15 +333,13 @@ PICO_INTERNAL int PicoPicoPCMSave(void *buffer, int length) { u8 *bp = buffer; - if (length < sizeof(xpcm) + sizeof(filters)) { + if (length < sizeof(xpcm)) { elprintf(EL_ANOMALY, "save buffer too small?"); return 0; } memcpy(bp, &xpcm, sizeof(xpcm)); bp += sizeof(xpcm); - memcpy(bp, filters, sizeof(filters)); - bp += sizeof(filters); return (bp - (u8*)buffer); } @@ -320,7 +350,4 @@ PICO_INTERNAL void PicoPicoPCMLoad(void *buffer, int length) if (length >= sizeof(xpcm)) memcpy(&xpcm, bp, sizeof(xpcm)); bp += sizeof(xpcm); - if (length >= sizeof(xpcm) + sizeof(filters)) - memcpy(filters, bp, sizeof(filters)); - bp += sizeof(filters); }