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authorMax Horn2007-07-01 16:31:26 +0000
committerMax Horn2007-07-01 16:31:26 +0000
commitf7041f94ce0a28ed21b918d1fb05ba66f131ea6d (patch)
tree69ea3449625ea2fcb56067e5b6e26ef7f2553e23 /sound/mods
parent94fab1c1513b26520cef88d5f9baf4ee2f4e094f (diff)
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Once again rewrite Paula code (addings lots of comments, doing proper wrap around at the ends of samples and some other tweaks). More to follow
svn-id: r27828
Diffstat (limited to 'sound/mods')
-rw-r--r--sound/mods/paula.cpp94
1 files changed, 56 insertions, 38 deletions
diff --git a/sound/mods/paula.cpp b/sound/mods/paula.cpp
index b4f7018343..d09ddbe76d 100644
--- a/sound/mods/paula.cpp
+++ b/sound/mods/paula.cpp
@@ -90,65 +90,83 @@ inline void mixBuffer(int16 *&buf, const int8 *data, frac_t &offset, frac_t rate
template<bool stereo>
int Paula::readBufferIntern(int16 *buffer, const int numSamples) {
- int voice;
- int samples;
- int nSamples;
-
- samples = _stereo ? numSamples / 2 : numSamples;
+ int samples = _stereo ? numSamples / 2 : numSamples;
while (samples > 0) {
+
+ // Handle 'interrupts'. This gives subclasses the chance to adjust the channel data
+ // (e.g. insert new samples, do pitch bending, whatever).
if (_curInt == _intFreq) {
interrupt();
_curInt = 0;
}
- nSamples = MIN(samples, _intFreq - _curInt);
- for (voice = 0; voice < NUM_VOICES; voice++) {
+
+ // Compute how many samples to generate: at most the requested number of samples,
+ // of course, but we may stop earlier when an 'interrupt' is expected.
+ const int nSamples = MIN(samples, _intFreq - _curInt);
+
+ // Loop over the four channels of the emulated Paula chip
+ for (int voice = 0; voice < NUM_VOICES; voice++) {
+
+ // No data, or paused -> skip channel
if (!_voice[voice].data || (_voice[voice].period <= 0))
continue;
+ // The Paula chip apparently run at 7.0937892 MHz. We combine this with
+ // the requested output sampling rate (typicall 44.1 kHz or 22.05 kHz)
+ // as well as the "period" of the channel we are processing right now,
+ // to compute the correct output 'rate'.
const double frequency = (7093789.2 / 2.0) / _voice[voice].period;
frac_t rate = doubleToFrac(frequency / _rate);
+
+ // Cap the volume
+ _voice[voice].volume = MIN((byte) 0x40, _voice[voice].volume);
+
+ // Cache some data (helps the compiler to optimize the code, by
+ // indirectly telling it that no data aliasing can occur).
frac_t offset = _voice[voice].offset;
frac_t sLen = intToFrac(_voice[voice].length);
-
const int8 *data = _voice[voice].data;
int16 *p = buffer;
int end = 0;
-
- _voice[voice].volume = MIN((byte) 0x40, _voice[voice].volume);
- // If looping has been enabled and we see that we will have to loop
- // to generate enough samples, then use the "loop" branch.
- if ((_voice[voice].lengthRepeat > 2) &&
- (offset + nSamples * rate >= sLen)) {
- int neededSamples = nSamples;
-
+ int neededSamples = nSamples;
+
+ // Compute the number of samples to generate; that is, either generate
+ // just as many as were requested, or until the buffer is used up.
+ // Note that dividing two frac_t yields an integer (as the denominators
+ // cancel out each other).
+ // Note that 'end' could be 0 here. No harm in that :-).
+ end = MIN(neededSamples, (int)((sLen - offset + rate - 1) / rate));
+ mixBuffer<stereo>(p, data, offset, rate, end, _voice[voice].volume, _voice[voice].panning);
+ neededSamples -= end;
+
+ // If we have not yet generated enough samples, and looping is active: loop!
+ if (neededSamples > 0 && _voice[voice].lengthRepeat > 2) {
+
+ // At this point we know that we have used up all samples in the buffer, so reset it.
+ _voice[voice].data = data = _voice[voice].dataRepeat;
+ _voice[voice].length = _voice[voice].lengthRepeat;
+ sLen = intToFrac(_voice[voice].length);
+
+ // If the "rate" exceeds the sample rate, we would have to perform constant
+ // wrap arounds. So, apply the first step of the euclidean algorithm to
+ // achieve the same more efficiently: Take rate modulo sLen
+ if (sLen < rate)
+ rate %= sLen;
+
+ // Repeat as long as necessary.
while (neededSamples > 0) {
- if (sLen - offset < rate) {
- // This means that "rate" is too high, bigger than the sample size.
- // So we scale it down according to the euclidean algorithm.
- rate %= sLen - offset;
- }
+ offset %= sLen;
- end = MIN(neededSamples, (sLen - offset) / rate);
+ // Compute the number of samples to generate (see above) and mix 'em.
+ end = MIN(neededSamples, (int)((sLen - offset + rate - 1) / rate));
mixBuffer<stereo>(p, data, offset, rate, end, _voice[voice].volume, _voice[voice].panning);
- _voice[voice].offset = offset;
neededSamples -= end;
-
- // If we read beyond the sample end, loop back to the start.
- // TODO: Shouldn't we wrap around here?
- if (_voice[voice].offset + FRAC_ONE > sLen) {
- _voice[voice].data = data = _voice[voice].dataRepeat;
- _voice[voice].length = _voice[voice].lengthRepeat;
- _voice[voice].offset = offset = 0;
- sLen = intToFrac(_voice[voice].length);
- }
- }
- } else {
- if (offset < sLen) { // Sample data left?
- end = MIN(nSamples, (sLen - offset) / rate);
- mixBuffer<stereo>(p, data, offset, rate, end, _voice[voice].volume, _voice[voice].panning);
- _voice[voice].offset = offset;
}
}
+
+ // Write back the cached data
+ _voice[voice].offset = offset;
+
}
buffer += _stereo ? nSamples * 2 : nSamples;
_curInt += nSamples;