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authorChris Robinson <[email protected]>2017-01-24 19:03:51 -0800
committerChris Robinson <[email protected]>2017-01-24 19:03:51 -0800
commit1ebfce4cac35731f1df5702ce613eada81f6ffa5 (patch)
tree088280e9029af29f73a0a4949256f99d84074bc5 /Alc
parentf4d52f43d87c02769c7649b91ba4afc967e121d2 (diff)
Improve the ambisonic upscaling methods
This now takes advantage of the differences seen in generated decoder matrices for first-order compared to second- and third-order, such that with the appropriate frequency-dependent scaling applied to first-order content, the result is identical with a higher-order decoder matrix compared to a first- order matrix for the same layout.
Diffstat (limited to 'Alc')
-rw-r--r--Alc/bformatdec.c216
-rw-r--r--Alc/bformatdec.h18
-rw-r--r--Alc/panning.c69
3 files changed, 174 insertions, 129 deletions
diff --git a/Alc/bformatdec.c b/Alc/bformatdec.c
index f3cc476f..86300f7b 100644
--- a/Alc/bformatdec.c
+++ b/Alc/bformatdec.c
@@ -123,21 +123,6 @@ enum FreqBand {
};
/* These points are in AL coordinates! */
-static const ALfloat Ambi2DPoints[4][3] = {
- { -0.707106781f, 0.0f, -0.707106781f },
- { 0.707106781f, 0.0f, -0.707106781f },
- { -0.707106781f, 0.0f, 0.707106781f },
- { 0.707106781f, 0.0f, 0.707106781f },
-};
-static const ALfloat Ambi2DDecoder[4][FB_Max][MAX_AMBI_COEFFS] = {
- { { 3.53553391e-1f, 2.04124145e-1f, 0.0f, 2.04124145e-1f }, { 0.25f, 2.04124145e-1f, 0.0f, 2.04124145e-1f } },
- { { 3.53553391e-1f, -2.04124145e-1f, 0.0f, 2.04124145e-1f }, { 0.25f, -2.04124145e-1f, 0.0f, 2.04124145e-1f } },
- { { 3.53553391e-1f, 2.04124145e-1f, 0.0f, -2.04124145e-1f }, { 0.25f, 2.04124145e-1f, 0.0f, -2.04124145e-1f } },
- { { 3.53553391e-1f, -2.04124145e-1f, 0.0f, -2.04124145e-1f }, { 0.25f, -2.04124145e-1f, 0.0f, -2.04124145e-1f } },
-};
-static ALfloat Ambi2DEncoderT[4][MAX_AMBI_COEFFS];
-
-/* These points are in AL coordinates! */
static const ALfloat Ambi3DPoints[8][3] = {
{ -0.577350269f, 0.577350269f, -0.577350269f },
{ 0.577350269f, 0.577350269f, -0.577350269f },
@@ -158,7 +143,6 @@ static const ALfloat Ambi3DDecoder[8][FB_Max][MAX_AMBI_COEFFS] = {
{ { 0.25f, 0.1443375672f, -0.1443375672f, -0.1443375672f }, { 0.125f, 0.125f, -0.125f, -0.125f } },
{ { 0.25f, -0.1443375672f, -0.1443375672f, -0.1443375672f }, { 0.125f, -0.125f, -0.125f, -0.125f } },
};
-static ALfloat Ambi3DEncoderT[8][MAX_AMBI_COEFFS];
static RowMixerFunc MixMatrixRow = MixRow_C;
@@ -168,64 +152,14 @@ static alonce_flag bformatdec_inited = AL_ONCE_FLAG_INIT;
static void init_bformatdec(void)
{
- size_t i, j;
-
MixMatrixRow = SelectRowMixer();
-
- for(i = 0;i < COUNTOF(Ambi3DPoints);i++)
- CalcDirectionCoeffs(Ambi3DPoints[i], 0.0f, Ambi3DEncoderT[i]);
-
- for(i = 0;i < COUNTOF(Ambi2DPoints);i++)
- {
- CalcDirectionCoeffs(Ambi2DPoints[i], 0.0f, Ambi2DEncoderT[i]);
-
- /* Remove the skipped height-related coefficients for 2D rendering. */
- Ambi2DEncoderT[i][2] = Ambi2DEncoderT[i][3];
- Ambi2DEncoderT[i][3] = Ambi2DEncoderT[i][4];
- Ambi2DEncoderT[i][4] = Ambi2DEncoderT[i][8];
- Ambi2DEncoderT[i][5] = Ambi2DEncoderT[i][9];
- Ambi2DEncoderT[i][6] = Ambi2DEncoderT[i][15];
- for(j = 7;j < MAX_AMBI_COEFFS;j++)
- Ambi2DEncoderT[i][j] = 0.0f;
- }
-}
-
-
-/* This typedef is needed for SAFE_CONST to work. */
-typedef ALfloat ALfloatMAX_AMBI_COEFFS[MAX_AMBI_COEFFS];
-
-static void GenUpsamplerGains(const ALfloat (*restrict EncoderT)[MAX_AMBI_COEFFS],
- const ALfloat (*restrict Decoder)[FB_Max][MAX_AMBI_COEFFS],
- ALsizei InChannels,
- ALfloat (*restrict OutGains)[MAX_OUTPUT_CHANNELS][FB_Max],
- ALsizei OutChannels)
-{
- ALsizei i, j, k;
-
- /* Combine the matrices that do the in->virt and virt->out conversions so
- * we get a single in->out conversion. NOTE: the Encoder matrix and output
- * are transposed, so the input channels line up with the rows and the
- * output channels line up with the columns.
- */
- for(i = 0;i < 4;i++)
- {
- for(j = 0;j < OutChannels;j++)
- {
- ALfloat hfgain=0.0f, lfgain=0.0f;
- for(k = 0;k < InChannels;k++)
- {
- hfgain += Decoder[k][FB_HighFreq][i]*EncoderT[k][j];
- lfgain += Decoder[k][FB_LowFreq][i]*EncoderT[k][j];
- }
- OutGains[i][j][FB_HighFreq] = hfgain;
- OutGains[i][j][FB_LowFreq] = lfgain;
- }
- }
}
#define MAX_DELAY_LENGTH 128
+#define INVALID_UPSAMPLE_INDEX INT_MAX
+
/* NOTE: BandSplitter filters are unused with single-band decoding */
typedef struct BFormatDec {
ALboolean Enabled[MAX_OUTPUT_CHANNELS];
@@ -250,10 +184,12 @@ typedef struct BFormatDec {
} Delay[MAX_OUTPUT_CHANNELS];
struct {
- BandSplitter XOver[4];
+ ALsizei Index;
- ALfloat Gains[4][MAX_OUTPUT_CHANNELS][FB_Max];
- } UpSampler;
+ BandSplitter XOver;
+
+ ALfloat Gains[FB_Max];
+ } UpSampler[4];
ALsizei NumChannels;
ALboolean DualBand;
@@ -327,23 +263,41 @@ void bformatdec_reset(BFormatDec *dec, const AmbDecConf *conf, ALsizei chancount
else if(conf->CoeffScale == ADS_FuMa)
coeff_scale = FuMa2N3DScale;
+ memset(dec->UpSampler, 0, sizeof(dec->UpSampler));
ratio = 400.0f / (ALfloat)srate;
for(i = 0;i < 4;i++)
- bandsplit_init(&dec->UpSampler.XOver[i], ratio);
- memset(dec->UpSampler.Gains, 0, sizeof(dec->UpSampler.Gains));
+ bandsplit_init(&dec->UpSampler[i].XOver, ratio);
if((conf->ChanMask&AMBI_PERIPHONIC_MASK))
{
- GenUpsamplerGains(SAFE_CONST(ALfloatMAX_AMBI_COEFFS*,Ambi3DEncoderT),
- Ambi3DDecoder, COUNTOF(Ambi3DDecoder),
- dec->UpSampler.Gains, dec->NumChannels);
dec->Periphonic = AL_TRUE;
+
+ dec->UpSampler[0].Index = 0;
+ dec->UpSampler[0].Gains[FB_HighFreq] = (dec->NumChannels > 9) ? W_SCALE3D_THIRD :
+ (dec->NumChannels > 4) ? W_SCALE3D_SECOND : 1.0f;
+ dec->UpSampler[0].Gains[FB_LowFreq] = 1.0f;
+ for(i = 1;i < 4;i++)
+ {
+ dec->UpSampler[i].Index = i;
+ dec->UpSampler[i].Gains[FB_HighFreq] = (dec->NumChannels > 9) ? XYZ_SCALE3D_THIRD :
+ (dec->NumChannels > 4) ? XYZ_SCALE3D_SECOND : 1.0f;
+ dec->UpSampler[i].Gains[FB_LowFreq] = 1.0f;
+ }
}
else
{
- GenUpsamplerGains(SAFE_CONST(ALfloatMAX_AMBI_COEFFS*,Ambi2DEncoderT),
- Ambi2DDecoder, COUNTOF(Ambi2DDecoder),
- dec->UpSampler.Gains, dec->NumChannels);
dec->Periphonic = AL_FALSE;
+
+ dec->UpSampler[0].Index = 0;
+ dec->UpSampler[0].Gains[FB_HighFreq] = (dec->NumChannels > 5) ? W_SCALE2D_THIRD :
+ (dec->NumChannels > 3) ? W_SCALE2D_SECOND : 1.0f;
+ dec->UpSampler[0].Gains[FB_LowFreq] = 1.0f;
+ for(i = 1;i < 4;i++)
+ {
+ dec->UpSampler[i].Index = (i>2) ? i-1 : ((i==2) ? INVALID_UPSAMPLE_INDEX : i);
+ dec->UpSampler[i].Gains[FB_HighFreq] = (dec->NumChannels > 5) ? XYZ_SCALE2D_THIRD :
+ (dec->NumChannels > 3) ? XYZ_SCALE2D_SECOND : 1.0f;
+ dec->UpSampler[i].Gains[FB_LowFreq] = 1.0f;
+ }
}
maxdist = 0.0f;
@@ -585,35 +539,53 @@ void bformatdec_process(struct BFormatDec *dec, ALfloat (*restrict OutBuffer)[BU
void bformatdec_upSample(struct BFormatDec *dec, ALfloat (*restrict OutBuffer)[BUFFERSIZE], const ALfloat (*restrict InSamples)[BUFFERSIZE], ALsizei InChannels, ALsizei SamplesToDo)
{
- ALsizei i, j;
+ ALsizei i;
- /* This up-sampler is very simplistic. It essentially decodes the first-
- * order content to a square channel array (or cube if height is desired),
- * then encodes those points onto the higher order soundfield. The decoder
- * and encoder matrices have been combined to directly convert each input
- * channel to the output, without the need for storing the virtual channel
- * array.
+ /* This up-sampler leverages the differences observed in dual-band second-
+ * and third-order decoder matrices compared to first-order. For the same
+ * output channel configuration, the low-frequency matrix has identical
+ * coefficients in the shared input channels, while the high-frequency
+ * matrix has extra scalars applied to the W channel and X/Y/Z channels.
+ * Mixing the first-order content into the higher-order stream with the
+ * appropriate counter-scales applied to the HF response results in the
+ * subsequent higher-order decode generating the same response as a first-
+ * order decode.
*/
for(i = 0;i < InChannels;i++)
{
+ ALsizei dst_chan = dec->UpSampler[i].Index;
+ if(dst_chan == INVALID_UPSAMPLE_INDEX)
+ continue;
+
/* First, split the first-order components into low and high frequency
* bands.
*/
- bandsplit_process(&dec->UpSampler.XOver[i],
+ bandsplit_process(&dec->UpSampler[i].XOver,
dec->Samples[FB_HighFreq], dec->Samples[FB_LowFreq],
InSamples[i], SamplesToDo
);
/* Now write each band to the output. */
- for(j = 0;j < dec->NumChannels;j++)
- MixMatrixRow(OutBuffer[j], dec->UpSampler.Gains[i][j],
- SAFE_CONST(ALfloatBUFFERSIZE*,dec->Samples), FB_Max, 0,
- SamplesToDo
- );
+ MixMatrixRow(OutBuffer[dst_chan], dec->UpSampler[i].Gains,
+ SAFE_CONST(ALfloatBUFFERSIZE*,dec->Samples), FB_Max, 0,
+ SamplesToDo
+ );
}
}
+static ALsizei GetACNIndex(const BFChannelConfig *chans, ALsizei numchans, ALsizei acn)
+{
+ ALsizei i;
+ for(i = 0;i < numchans;i++)
+ {
+ if(chans[i].Index == acn)
+ return i;
+ }
+ return INVALID_UPSAMPLE_INDEX;
+}
+#define GetChannelForACN(b, a) GetACNIndex((b).Ambi.Map, (b).NumChannels, (a))
+
typedef struct AmbiUpsampler {
alignas(16) ALfloat Samples[FB_Max][BUFFERSIZE];
@@ -635,21 +607,65 @@ void ambiup_free(struct AmbiUpsampler *ambiup)
void ambiup_reset(struct AmbiUpsampler *ambiup, const ALCdevice *device)
{
- ALfloat gains[8][MAX_OUTPUT_CHANNELS];
ALfloat ratio;
- ALuint i;
+ size_t i;
ratio = 400.0f / (ALfloat)device->Frequency;
for(i = 0;i < 4;i++)
bandsplit_init(&ambiup->XOver[i], ratio);
- for(i = 0;i < COUNTOF(Ambi3DEncoderT);i++)
- ComputePanningGains(device->Dry, Ambi3DEncoderT[i], 1.0f, gains[i]);
-
memset(ambiup->Gains, 0, sizeof(ambiup->Gains));
- GenUpsamplerGains(SAFE_CONST(ALfloatMAX_AMBI_COEFFS*,gains),
- Ambi3DDecoder, COUNTOF(Ambi3DDecoder),
- ambiup->Gains, device->Dry.NumChannels);
+ if(device->Dry.CoeffCount > 0)
+ {
+ ALfloat encgains[8][MAX_OUTPUT_CHANNELS];
+ ALsizei j;
+ size_t k;
+
+ for(i = 0;i < COUNTOF(Ambi3DPoints);i++)
+ {
+ ALfloat coeffs[MAX_AMBI_COEFFS] = { 0.0f };
+ CalcDirectionCoeffs(Ambi3DPoints[i], 0.0f, coeffs);
+ ComputePanningGains(device->Dry, coeffs, 1.0f, encgains[i]);
+ }
+
+ /* Combine the matrices that do the in->virt and virt->out conversions
+ * so we get a single in->out conversion. NOTE: the Encoder matrix
+ * (encgains) and output are transposed, so the input channels line up
+ * with the rows and the output channels line up with the columns.
+ */
+ for(i = 0;i < 4;i++)
+ {
+ for(j = 0;j < device->Dry.NumChannels;j++)
+ {
+ ALfloat hfgain=0.0f, lfgain=0.0f;
+ for(k = 0;k < COUNTOF(Ambi3DDecoder);k++)
+ {
+ hfgain += Ambi3DDecoder[k][FB_HighFreq][i]*encgains[k][j];
+ lfgain += Ambi3DDecoder[k][FB_LowFreq][i]*encgains[k][j];
+ }
+ ambiup->Gains[i][j][FB_HighFreq] = hfgain;
+ ambiup->Gains[i][j][FB_LowFreq] = lfgain;
+ }
+ }
+ }
+ else
+ {
+ /* Assumes full 3D/periphonic on the input and output mixes! */
+ ALfloat w_scale = (device->Dry.NumChannels > 9) ? W_SCALE3D_THIRD :
+ (device->Dry.NumChannels > 4) ? W_SCALE3D_SECOND : 1.0f;
+ ALfloat xyz_scale = (device->Dry.NumChannels > 9) ? XYZ_SCALE3D_THIRD :
+ (device->Dry.NumChannels > 4) ? XYZ_SCALE3D_SECOND : 1.0f;
+ for(i = 0;i < 4;i++)
+ {
+ ALsizei index = GetChannelForACN(device->Dry, i);
+ if(index != INVALID_UPSAMPLE_INDEX)
+ {
+ ALfloat scale = device->Dry.Ambi.Map[index].Scale;
+ ambiup->Gains[i][index][FB_HighFreq] = scale * ((i==0) ? w_scale : xyz_scale);
+ ambiup->Gains[i][index][FB_LowFreq] = scale;
+ }
+ }
+ }
}
void ambiup_process(struct AmbiUpsampler *ambiup, ALfloat (*restrict OutBuffer)[BUFFERSIZE], ALsizei OutChannels, const ALfloat (*restrict InSamples)[BUFFERSIZE], ALsizei SamplesToDo)
diff --git a/Alc/bformatdec.h b/Alc/bformatdec.h
index 3f240e54..7024b003 100644
--- a/Alc/bformatdec.h
+++ b/Alc/bformatdec.h
@@ -3,6 +3,24 @@
#include "alMain.h"
+
+/* These are the necessary scales for first-order HF responses to play over
+ * higher-order 2D (non-periphonic) decoders.
+ */
+#define W_SCALE2D_SECOND 1.224744871f /* sqrt(1.5) */
+#define XYZ_SCALE2D_SECOND 1.0f
+#define W_SCALE2D_THIRD 1.414213562f /* sqrt(2) */
+#define XYZ_SCALE2D_THIRD 1.082392196f
+
+/* These are the necessary scales for first-order HF responses to play over
+ * higher-order 3D (periphonic) decoders.
+ */
+#define W_SCALE3D_SECOND 1.341640787f /* sqrt(1.8) */
+#define XYZ_SCALE3D_SECOND 1.0f
+#define W_SCALE3D_THIRD 1.695486018f
+#define XYZ_SCALE3D_THIRD 1.136697713f
+
+
struct AmbDecConf;
struct BFormatDec;
struct AmbiUpsampler;
diff --git a/Alc/panning.c b/Alc/panning.c
index 32227b04..9b6f9b44 100644
--- a/Alc/panning.c
+++ b/Alc/panning.c
@@ -39,12 +39,6 @@
extern inline void CalcXYZCoeffs(ALfloat x, ALfloat y, ALfloat z, ALfloat spread, ALfloat coeffs[MAX_AMBI_COEFFS]);
-#define ZERO_ORDER_SCALE 0.0f
-#define FIRST_ORDER_SCALE 1.0f
-#define SECOND_ORDER_SCALE (1.0f / 1.22474f)
-#define THIRD_ORDER_SCALE (1.0f / 1.30657f)
-
-
static const ALsizei FuMa2ACN[MAX_AMBI_COEFFS] = {
0, /* W */
3, /* X */
@@ -499,59 +493,50 @@ static void InitPanning(ALCdevice *device)
{
const ChannelMap *chanmap = NULL;
ALsizei coeffcount = 0;
- ALfloat ambiscale;
ALsizei count = 0;
ALsizei i, j;
- ambiscale = 1.0f;
switch(device->FmtChans)
{
case DevFmtMono:
count = COUNTOF(MonoCfg);
chanmap = MonoCfg;
- ambiscale = ZERO_ORDER_SCALE;
coeffcount = 1;
break;
case DevFmtStereo:
count = COUNTOF(StereoCfg);
chanmap = StereoCfg;
- ambiscale = FIRST_ORDER_SCALE;
coeffcount = 4;
break;
case DevFmtQuad:
count = COUNTOF(QuadCfg);
chanmap = QuadCfg;
- ambiscale = FIRST_ORDER_SCALE;
coeffcount = 4;
break;
case DevFmtX51:
count = COUNTOF(X51SideCfg);
chanmap = X51SideCfg;
- ambiscale = SECOND_ORDER_SCALE;
coeffcount = 9;
break;
case DevFmtX51Rear:
count = COUNTOF(X51RearCfg);
chanmap = X51RearCfg;
- ambiscale = SECOND_ORDER_SCALE;
coeffcount = 9;
break;
case DevFmtX61:
count = COUNTOF(X61Cfg);
chanmap = X61Cfg;
- ambiscale = SECOND_ORDER_SCALE;
coeffcount = 9;
break;
case DevFmtX71:
count = COUNTOF(X71Cfg);
chanmap = X71Cfg;
- ambiscale = THIRD_ORDER_SCALE;
coeffcount = 16;
break;
@@ -603,16 +588,23 @@ static void InitPanning(ALCdevice *device)
}
else
{
+ ALfloat w_scale, xyz_scale;
+
SetChannelMap(device->RealOut.ChannelName, device->Dry.Ambi.Coeffs,
chanmap, count, &device->Dry.NumChannels);
device->Dry.CoeffCount = coeffcount;
+ w_scale = (device->Dry.CoeffCount > 9) ? W_SCALE2D_THIRD :
+ (device->Dry.CoeffCount > 4) ? W_SCALE2D_SECOND : 1.0f;
+ xyz_scale = (device->Dry.CoeffCount > 9) ? XYZ_SCALE2D_THIRD :
+ (device->Dry.CoeffCount > 4) ? XYZ_SCALE2D_SECOND : 1.0f;
+
memset(&device->FOAOut.Ambi, 0, sizeof(device->FOAOut.Ambi));
- for(i = 0;i < (ALsizei)device->Dry.NumChannels;i++)
+ for(i = 0;i < device->Dry.NumChannels;i++)
{
- device->FOAOut.Ambi.Coeffs[i][0] = device->Dry.Ambi.Coeffs[i][0];
+ device->FOAOut.Ambi.Coeffs[i][0] = device->Dry.Ambi.Coeffs[i][0] * w_scale;
for(j = 1;j < 4;j++)
- device->FOAOut.Ambi.Coeffs[i][j] = device->Dry.Ambi.Coeffs[i][j] * ambiscale;
+ device->FOAOut.Ambi.Coeffs[i][j] = device->Dry.Ambi.Coeffs[i][j] * xyz_scale;
}
device->FOAOut.CoeffCount = 4;
}
@@ -622,21 +614,40 @@ static void InitCustomPanning(ALCdevice *device, const AmbDecConf *conf, const A
{
ChannelMap chanmap[MAX_OUTPUT_CHANNELS];
const ALfloat *coeff_scale = UnitScale;
- ALfloat ambiscale = 1.0f;
+ ALfloat w_scale = 1.0f;
+ ALfloat xyz_scale = 1.0f;
ALsizei i, j;
if(conf->FreqBands != 1)
ERR("Basic renderer uses the high-frequency matrix as single-band (xover_freq = %.0fhz)\n",
conf->XOverFreq);
- if(conf->ChanMask > 0x1ff)
- ambiscale = THIRD_ORDER_SCALE;
- else if(conf->ChanMask > 0xf)
- ambiscale = SECOND_ORDER_SCALE;
- else if(conf->ChanMask > 0x1)
- ambiscale = FIRST_ORDER_SCALE;
+ if((conf->ChanMask&AMBI_PERIPHONIC_MASK))
+ {
+ if(conf->ChanMask > 0x1ff)
+ {
+ w_scale = W_SCALE3D_THIRD;
+ xyz_scale = XYZ_SCALE3D_THIRD;
+ }
+ else if(conf->ChanMask > 0xf)
+ {
+ w_scale = W_SCALE3D_SECOND;
+ xyz_scale = XYZ_SCALE3D_SECOND;
+ }
+ }
else
- ambiscale = 0.0f;
+ {
+ if(conf->ChanMask > 0x1ff)
+ {
+ w_scale = W_SCALE2D_THIRD;
+ xyz_scale = XYZ_SCALE2D_THIRD;
+ }
+ else if(conf->ChanMask > 0xf)
+ {
+ w_scale = W_SCALE2D_SECOND;
+ xyz_scale = XYZ_SCALE2D_SECOND;
+ }
+ }
if(conf->CoeffScale == ADS_SN3D)
coeff_scale = SN3D2N3DScale;
@@ -670,11 +681,11 @@ static void InitCustomPanning(ALCdevice *device, const AmbDecConf *conf, const A
(conf->ChanMask > 0xf) ? 9 : 4;
memset(&device->FOAOut.Ambi, 0, sizeof(device->FOAOut.Ambi));
- for(i = 0;i < (ALsizei)device->Dry.NumChannels;i++)
+ for(i = 0;i < device->Dry.NumChannels;i++)
{
- device->FOAOut.Ambi.Coeffs[i][0] = device->Dry.Ambi.Coeffs[i][0];
+ device->FOAOut.Ambi.Coeffs[i][0] = device->Dry.Ambi.Coeffs[i][0] * w_scale;
for(j = 1;j < 4;j++)
- device->FOAOut.Ambi.Coeffs[i][j] = device->Dry.Ambi.Coeffs[i][j] * ambiscale;
+ device->FOAOut.Ambi.Coeffs[i][j] = device->Dry.Ambi.Coeffs[i][j] * xyz_scale;
}
device->FOAOut.CoeffCount = 4;
}