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-rw-r--r--audio/mods/paula.cpp117
-rw-r--r--audio/mods/paula.h26
2 files changed, 135 insertions, 8 deletions
diff --git a/audio/mods/paula.cpp b/audio/mods/paula.cpp
index 0ebf3bc32a..283c0cbb7b 100644
--- a/audio/mods/paula.cpp
+++ b/audio/mods/paula.cpp
@@ -20,14 +20,37 @@
*
*/
+/*
+ * The low-pass filter code is based on UAE's audio filter code
+ * found in audio.c. UAE is licensed under the terms of the GPLv2.
+ *
+ * audio.c in UAE states the following:
+ * Copyright 1995, 1996, 1997 Bernd Schmidt
+ * Copyright 1996 Marcus Sundberg
+ * Copyright 1996 Manfred Thole
+ * Copyright 2006 Toni Wilen
+ */
+
+#include <math.h>
+
+#include "common/scummsys.h"
+
#include "audio/mods/paula.h"
#include "audio/null.h"
namespace Audio {
-Paula::Paula(bool stereo, int rate, uint interruptFreq) :
+Paula::Paula(bool stereo, int rate, uint interruptFreq, FilterMode filterMode) :
_stereo(stereo), _rate(rate), _periodScale((double)kPalPaulaClock / rate), _intFreq(interruptFreq) {
+ _filterState.mode = filterMode;
+ _filterState.ledFilter = false;
+ filterResetState();
+
+ _filterState.a0[0] = filterCalculateA0(rate, 6200);
+ _filterState.a0[1] = filterCalculateA0(rate, 20000);
+ _filterState.a0[2] = filterCalculateA0(rate, 7000);
+
clearVoices();
_voice[0].panning = 191;
_voice[1].panning = 63;
@@ -73,12 +96,70 @@ int Paula::readBuffer(int16 *buffer, const int numSamples) {
return readBufferIntern<false>(buffer, numSamples);
}
+/* Denormals are very small floating point numbers that force FPUs into slow
+ * mode. All lowpass filters using floats are suspectible to denormals unless
+ * a small offset is added to avoid very small floating point numbers.
+ */
+#define DENORMAL_OFFSET (1E-10)
+
+/* Based on UAE.
+ * Original comment in UAE:
+ *
+ * Amiga has two separate filtering circuits per channel, a static RC filter
+ * on A500 and the LED filter. This code emulates both.
+ *
+ * The Amiga filtering circuitry depends on Amiga model. Older Amigas seem
+ * to have a 6 dB/oct RC filter with cutoff frequency such that the -6 dB
+ * point for filter is reached at 6 kHz, while newer Amigas have no filtering.
+ *
+ * The LED filter is complicated, and we are modelling it with a pair of
+ * RC filters, the other providing a highboost. The LED starts to cut
+ * into signal somewhere around 5-6 kHz, and there's some kind of highboost
+ * in effect above 12 kHz. Better measurements are required.
+ *
+ * The current filtering should be accurate to 2 dB with the filter on,
+ * and to 1 dB with the filter off.
+ */
+inline int32 filter(int32 input, Paula::FilterState &state, int voice) {
+ float normalOutput, ledOutput;
+
+ switch (state.mode) {
+ case Paula::kFilterModeA500:
+ state.rc[voice][0] = state.a0[0] * input + (1 - state.a0[0]) * state.rc[voice][0] + DENORMAL_OFFSET;
+ state.rc[voice][1] = state.a0[1] * state.rc[voice][0] + (1-state.a0[1]) * state.rc[voice][1];
+ normalOutput = state.rc[voice][1];
+
+ state.rc[voice][2] = state.a0[2] * normalOutput + (1 - state.a0[2]) * state.rc[voice][2];
+ state.rc[voice][3] = state.a0[2] * state.rc[voice][2] + (1 - state.a0[2]) * state.rc[voice][3];
+ state.rc[voice][4] = state.a0[2] * state.rc[voice][3] + (1 - state.a0[2]) * state.rc[voice][4];
+
+ ledOutput = state.rc[voice][4];
+ break;
+
+ case Paula::kFilterModeA1200:
+ normalOutput = input;
+
+ state.rc[voice][1] = state.a0[2] * normalOutput + (1 - state.a0[2]) * state.rc[voice][1] + DENORMAL_OFFSET;
+ state.rc[voice][2] = state.a0[2] * state.rc[voice][1] + (1 - state.a0[2]) * state.rc[voice][2];
+ state.rc[voice][3] = state.a0[2] * state.rc[voice][2] + (1 - state.a0[2]) * state.rc[voice][3];
+
+ ledOutput = state.rc[voice][3];
+ break;
+
+ case Paula::kFilterModeNone:
+ default:
+ return input;
+
+ }
+
+ return CLIP<int32>(state.ledFilter ? ledOutput : normalOutput, -32768, 32767);
+}
template<bool stereo>
-inline int mixBuffer(int16 *&buf, const int8 *data, Paula::Offset &offset, frac_t rate, int neededSamples, uint bufSize, byte volume, byte panning) {
+inline int mixBuffer(int16 *&buf, const int8 *data, Paula::Offset &offset, frac_t rate, int neededSamples, uint bufSize, byte volume, byte panning, Paula::FilterState &filterState, int voice) {
int samples;
for (samples = 0; samples < neededSamples && offset.int_off < bufSize; ++samples) {
- const int32 tmp = ((int32) data[offset.int_off]) * volume;
+ const int32 tmp = filter(((int32) data[offset.int_off]) * volume, filterState, voice);
if (stereo) {
*buf++ += (tmp * (255 - panning)) >> 7;
*buf++ += (tmp * (panning)) >> 7;
@@ -142,7 +223,7 @@ int Paula::readBufferIntern(int16 *buffer, const int numSamples) {
// by the OS/2 version of Hopkins FBI.
// Mix the generated samples into the output buffer
- neededSamples -= mixBuffer<stereo>(p, ch.data, ch.offset, rate, neededSamples, ch.length, ch.volume, ch.panning);
+ neededSamples -= mixBuffer<stereo>(p, ch.data, ch.offset, rate, neededSamples, ch.length, ch.volume, ch.panning, _filterState, voice);
// Wrap around if necessary
if (ch.offset.int_off >= ch.length) {
@@ -164,7 +245,7 @@ int Paula::readBufferIntern(int16 *buffer, const int numSamples) {
// Repeat as long as necessary.
while (neededSamples > 0) {
// Mix the generated samples into the output buffer
- neededSamples -= mixBuffer<stereo>(p, ch.data, ch.offset, rate, neededSamples, ch.length, ch.volume, ch.panning);
+ neededSamples -= mixBuffer<stereo>(p, ch.data, ch.offset, rate, neededSamples, ch.length, ch.volume, ch.panning, _filterState, voice);
if (ch.offset.int_off >= ch.length) {
// Wrap around. See also the note above.
@@ -182,6 +263,32 @@ int Paula::readBufferIntern(int16 *buffer, const int numSamples) {
return numSamples;
}
+void Paula::filterResetState() {
+ for (int i = 0; i < NUM_VOICES; i++)
+ for (int j = 0; j < 5; j++)
+ _filterState.rc[i][j] = 0.0f;
+}
+
+/* Based on UAE.
+ * Original comment in UAE:
+ *
+ * This computes the 1st order low-pass filter term b0.
+ * The a1 term is 1.0 - b0. The center frequency marks the -3 dB point.
+ */
+float Paula::filterCalculateA0(int rate, int cutoff) {
+ float omega;
+ /* The BLT correction formula below blows up if the cutoff is above nyquist. */
+ if (cutoff >= rate / 2)
+ return 1.0;
+
+ omega = 2 * M_PI * cutoff / rate;
+ /* Compensate for the bilinear transformation. This allows us to specify the
+ * stop frequency more exactly, but the filter becomes less steep further
+ * from stopband. */
+ omega = tan(omega / 2) * 2;
+ return 1 / (1 + 1 / omega);
+}
+
} // End of namespace Audio
diff --git a/audio/mods/paula.h b/audio/mods/paula.h
index a1c3182c2c..93d683064a 100644
--- a/audio/mods/paula.h
+++ b/audio/mods/paula.h
@@ -46,6 +46,12 @@ public:
kNtscPaulaClock = kNtscSystemClock / 2
};
+ enum FilterMode {
+ kFilterModeNone = 0,
+ kFilterModeA500,
+ kFilterModeA1200
+ };
+
/* TODO: Document this */
struct Offset {
uint int_off; // integral part of the offset
@@ -54,7 +60,16 @@ public:
explicit Offset(int off = 0) : int_off(off), rem_off(0) {}
};
- Paula(bool stereo = false, int rate = 44100, uint interruptFreq = 0);
+ struct FilterState {
+ FilterMode mode;
+ bool ledFilter;
+
+ float a0[3];
+ float rc[NUM_VOICES][5];
+ };
+
+ Paula(bool stereo = false, int rate = 44100, uint interruptFreq = 0,
+ FilterMode filterMode = kFilterModeA1200);
~Paula();
bool playing() const { return _playing; }
@@ -70,7 +85,7 @@ public:
}
void clearVoice(byte voice);
void clearVoices() { for (int i = 0; i < NUM_VOICES; ++i) clearVoice(i); }
- void startPlay() { _playing = true; }
+ void startPlay() { filterResetState(); _playing = true; }
void stopPlay() { _playing = false; }
void pausePlay(bool pause) { _playing = !pause; }
@@ -184,7 +199,7 @@ protected:
}
void setAudioFilter(bool enable) {
- // TODO: implement
+ _filterState.ledFilter = enable;
}
private:
@@ -198,8 +213,13 @@ private:
uint32 _timerBase;
bool _playing;
+ FilterState _filterState;
+
template<bool stereo>
int readBufferIntern(int16 *buffer, const int numSamples);
+
+ void filterResetState();
+ float filterCalculateA0(int rate, int cutoff);
};
} // End of namespace Audio