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-rw-r--r--Alc/hrtf.c140
1 files changed, 138 insertions, 2 deletions
diff --git a/Alc/hrtf.c b/Alc/hrtf.c
index 4e03e198..6edc37e7 100644
--- a/Alc/hrtf.c
+++ b/Alc/hrtf.c
@@ -80,6 +80,37 @@ static void CalcAzIndices(ALuint evidx, ALfloat az, ALuint *azidx, ALfloat *azmu
*azmu = az - (ALuint)az;
}
+// Calculates the normalized HRTF transition factor (delta) from the changes
+// in gain and listener to source angle between updates. The result is a
+// normalized delta factor than can be used to calculate moving HRIR stepping
+// values.
+ALfloat CalcHrtfDelta(ALfloat oldGain, ALfloat newGain, const ALfloat olddir[3], const ALfloat newdir[3])
+{
+ ALfloat gainChange, angleChange, delta;
+
+ // Calculate the normalized dB gain change.
+ gainChange = aluFabs((log10(__max(newGain, 0.0001f)) -
+ log10(__max(oldGain, 0.0001f))) / log10(0.0001f));
+
+ // Calculate the normalized listener to source angle change when there is
+ // enough gain to notice it.
+ angleChange = 0.0f;
+ if(gainChange > 0.0001f || newGain > 0.0001f)
+ {
+ // No angle change when the directions are equal or degenerate (when
+ // both have zero length).
+ if(newdir[0]-olddir[0] || newdir[1]-olddir[1] || newdir[2]-olddir[2])
+ angleChange = aluAcos(olddir[0]*newdir[0] +
+ olddir[1]*newdir[1] +
+ olddir[2]*newdir[2]) / M_PI;
+
+ }
+
+ // Use the largest of the two changes for the delta factor.
+ delta = __max(gainChange, angleChange) * 2.0f;
+ return __min(delta, 1.0f);
+}
+
// Calculates static HRIR coefficients and delays for the given polar
// elevation and azimuth in radians. Linear interpolation is used to
// increase the apparent resolution of the HRIR dataset. The coefficients
@@ -144,10 +175,115 @@ void GetLerpedHrtfCoeffs(ALfloat elevation, ALfloat azimuth, ALfloat gain, ALflo
// Calculate the HRIR delays using linear interpolation.
delays[0] = (ALuint)(lerp(lerp(Hrtf.delays[lidx[0]], Hrtf.delays[lidx[1]], mu[0]),
lerp(Hrtf.delays[lidx[2]], Hrtf.delays[lidx[3]], mu[1]),
- mu[2]) + 0.5f);
+ mu[2]) * 65536.0f);
+ delays[1] = (ALuint)(lerp(lerp(Hrtf.delays[ridx[0]], Hrtf.delays[ridx[1]], mu[0]),
+ lerp(Hrtf.delays[ridx[2]], Hrtf.delays[ridx[3]], mu[1]),
+ mu[2]) * 65536.0f);
+}
+
+// Calculates the moving HRIR target coefficients, target delays, and
+// stepping values for the given polar elevation and azimuth in radians.
+// Linear interpolation is used to increase the apparent resolution of the
+// HRIR dataset. The coefficients are also normalized and attenuated by the
+// specified gain. Stepping resolution and count is determined using the
+// given delta factor between 0.0 and 1.0.
+ALint GetMovingHrtfCoeffs(ALfloat elevation, ALfloat azimuth, ALfloat gain, ALfloat delta, ALint counter, ALfloat (*coeffs)[2], ALuint *delays, ALfloat (*coeffStep)[2], ALint *delayStep)
+{
+ ALfloat step;
+ ALuint evidx[2], azidx[2];
+ ALfloat mu[3];
+ ALuint lidx[4], ridx[4];
+ ALuint i;
+ ALfloat left, right;
+
+ // Claculate elevation indices and interpolation factor.
+ CalcEvIndices(elevation, evidx, &mu[2]);
+
+ // Calculate azimuth indices and interpolation factor for the first
+ // elevation.
+ CalcAzIndices(evidx[0], azimuth, azidx, &mu[0]);
+
+ // Calculate the first set of linear HRIR indices for left and right
+ // channels.
+ lidx[0] = evOffset[evidx[0]] + azidx[0];
+ lidx[1] = evOffset[evidx[0]] + azidx[1];
+ ridx[0] = evOffset[evidx[0]] + ((azCount[evidx[0]]-azidx[0]) % azCount[evidx[0]]);
+ ridx[1] = evOffset[evidx[0]] + ((azCount[evidx[0]]-azidx[1]) % azCount[evidx[0]]);
+
+ // Calculate azimuth indices and interpolation factor for the second
+ // elevation.
+ CalcAzIndices(evidx[1], azimuth, azidx, &mu[1]);
+
+ // Calculate the second set of linear HRIR indices for left and right
+ // channels.
+ lidx[2] = evOffset[evidx[1]] + azidx[0];
+ lidx[3] = evOffset[evidx[1]] + azidx[1];
+ ridx[2] = evOffset[evidx[1]] + ((azCount[evidx[1]]-azidx[0]) % azCount[evidx[1]]);
+ ridx[3] = evOffset[evidx[1]] + ((azCount[evidx[1]]-azidx[1]) % azCount[evidx[1]]);
+
+ // Calculate the stepping parameters.
+ delta = __max(0.015f * delta * Hrtf.sampleRate, 1.0f);
+ step = 1.0f / delta;
+
+ // Calculate the normalized and attenuated target HRIR coefficients using
+ // linear interpolation when there is enough gain to warrant it. Zero
+ // the target coefficients if gain is too low. Then calculate the
+ // coefficient stepping values using the target and previous running
+ // coefficients.
+ if(gain > 0.0001f)
+ {
+ ALdouble scale = gain * (1.0/32767.0);
+ for(i = 0;i < HRIR_LENGTH;i++)
+ {
+ left = coeffs[i][0] - (coeffStep[i][0] * counter);
+ right = coeffs[i][1] - (coeffStep[i][1] * counter);
+
+ coeffs[i][0] = lerp(lerp(Hrtf.coeffs[lidx[0]][i], Hrtf.coeffs[lidx[1]][i], mu[0]),
+ lerp(Hrtf.coeffs[lidx[2]][i], Hrtf.coeffs[lidx[3]][i], mu[1]),
+ mu[2]) * scale;
+ coeffs[i][1] = lerp(lerp(Hrtf.coeffs[ridx[0]][i], Hrtf.coeffs[ridx[1]][i], mu[0]),
+ lerp(Hrtf.coeffs[ridx[2]][i], Hrtf.coeffs[ridx[3]][i], mu[1]),
+ mu[2]) * scale;
+
+ coeffStep[i][0] = step * (coeffs[i][0] - left);
+ coeffStep[i][1] = step * (coeffs[i][1] - right);
+ }
+ }
+ else
+ {
+ for(i = 0;i < HRIR_LENGTH;i++)
+ {
+ left = coeffs[i][0] - (coeffStep[i][0] * counter);
+ right = coeffs[i][1] - (coeffStep[i][1] * counter);
+
+ coeffs[i][0] = 0.0f;
+ coeffs[i][1] = 0.0f;
+
+ coeffStep[i][0] = step * -left;
+ coeffStep[i][1] = step * -right;
+ }
+ }
+
+ // Calculate the HRIR delays using linear interpolation. Then calculate
+ // the delay stepping values using the target and previous running
+ // delays.
+ left = delays[0] - (delayStep[0] * counter);
+ right = delays[1] - (delayStep[1] * counter);
+
+ delays[0] = (ALuint)(lerp(lerp(Hrtf.delays[lidx[0]], Hrtf.delays[lidx[1]], mu[0]),
+ lerp(Hrtf.delays[lidx[2]], Hrtf.delays[lidx[3]], mu[1]),
+ mu[2]) * 65536.0f);
delays[1] = (ALuint)(lerp(lerp(Hrtf.delays[ridx[0]], Hrtf.delays[ridx[1]], mu[0]),
lerp(Hrtf.delays[ridx[2]], Hrtf.delays[ridx[3]], mu[1]),
- mu[2]) + 0.5f);
+ mu[2]) * 65536.0f);
+
+ delayStep[0] = (ALint)(step * (delays[0] - left));
+ delayStep[1] = (ALint)(step * (delays[1] - right));
+
+ // The stepping count is the number of samples necessary for the HRIR to
+ // complete its transition. The mixer will only apply stepping for this
+ // many samples.
+ return (ALuint)delta;
}
ALCboolean IsHrtfCompatible(ALCdevice *device)