4 files changed, 48 insertions, 48 deletions

diff --git a/Alc/filters/defs.h b/Alc/filters/defs.h
index 19514b62..fb8c9312 100644
--- a/Alc/filters/defs.h
+++ b/Alc/filters/defs.h
@@ -35,11 +35,11 @@ enum class BiquadType {
 
 struct BiquadFilter {
     /* Last two delayed components for direct form II. */
-    ALfloat z1{0.0f}, z2{0.0f};
+    float z1{0.0f}, z2{0.0f};
     /* Transfer function coefficients "b" (numerator) */
-    ALfloat b0{1.0f}, b1{0.0f}, b2{0.0f};
+    float b0{1.0f}, b1{0.0f}, b2{0.0f};
     /* Transfer function coefficients "a" (denominator; a0 is pre-applied). */
-    ALfloat a1{0.0f}, a2{0.0f};
+    float a1{0.0f}, a2{0.0f};
 };
 /* Currently only a C-based filter process method is implemented. */
 #define BiquadFilter_process BiquadFilter_processC
@@ -50,7 +50,7 @@ struct BiquadFilter {
  * \param gain 0 < gain
  * \param slope 0 < slope <= 1
  */
-inline ALfloat calc_rcpQ_from_slope(ALfloat gain, ALfloat slope)
+inline float calc_rcpQ_from_slope(float gain, float slope)
 {
     return std::sqrt((gain + 1.0f/gain)*(1.0f/slope - 1.0f) + 2.0f);
 }
@@ -60,9 +60,9 @@ inline ALfloat calc_rcpQ_from_slope(ALfloat gain, ALfloat slope)
  * \param f0norm 0 < f0norm < 0.5.
  * \param bandwidth 0 < bandwidth
  */
-inline ALfloat calc_rcpQ_from_bandwidth(ALfloat f0norm, ALfloat bandwidth)
+inline ALfloat calc_rcpQ_from_bandwidth(float f0norm, float bandwidth)
 {
-    ALfloat w0 = F_TAU * f0norm;
+    float w0 = F_TAU * f0norm;
     return 2.0f*std::sinh(std::log(2.0f)/2.0f*bandwidth*w0/std::sin(w0));
 }
 
@@ -87,7 +87,7 @@ inline void BiquadFilter_clear(BiquadFilter *filter)
  *             band. Can be generated from calc_rcpQ_from_slope or
  *             calc_rcpQ_from_bandwidth depending on the available data.
  */
-void BiquadFilter_setParams(BiquadFilter *filter, BiquadType type, ALfloat gain, ALfloat f0norm, ALfloat rcpQ);
+void BiquadFilter_setParams(BiquadFilter *filter, BiquadType type, float gain, float f0norm, float rcpQ);
 
 inline void BiquadFilter_copyParams(BiquadFilter *RESTRICT dst, const BiquadFilter *RESTRICT src)
 {
@@ -98,9 +98,9 @@ inline void BiquadFilter_copyParams(BiquadFilter *RESTRICT dst, const BiquadFilt
     dst->a2 = src->a2;
 }
 
-void BiquadFilter_processC(BiquadFilter *filter, ALfloat *RESTRICT dst, const ALfloat *RESTRICT src, ALsizei numsamples);
+void BiquadFilter_processC(BiquadFilter *filter, float *RESTRICT dst, const float *RESTRICT src, int numsamples);
 
-inline void BiquadFilter_passthru(BiquadFilter *filter, ALsizei numsamples)
+inline void BiquadFilter_passthru(BiquadFilter *filter, int numsamples)
 {
     if(LIKELY(numsamples >= 2))
     {
diff --git a/Alc/filters/filter.cpp b/Alc/filters/filter.cpp
index 5dc5d9b4..980841c0 100644
--- a/Alc/filters/filter.cpp
+++ b/Alc/filters/filter.cpp
@@ -10,12 +10,12 @@
 #include "defs.h"
 
 
-void BiquadFilter_setParams(BiquadFilter *filter, BiquadType type, ALfloat gain, ALfloat f0norm, ALfloat rcpQ)
+void BiquadFilter_setParams(BiquadFilter *filter, BiquadType type, float gain, float f0norm, float rcpQ)
 {
-    ALfloat alpha, sqrtgain_alpha_2;
-    ALfloat w0, sin_w0, cos_w0;
-    ALfloat a[3] = { 1.0f, 0.0f, 0.0f };
-    ALfloat b[3] = { 1.0f, 0.0f, 0.0f };
+    float alpha, sqrtgain_alpha_2;
+    float w0, sin_w0, cos_w0;
+    float a[3] = { 1.0f, 0.0f, 0.0f };
+    float b[3] = { 1.0f, 0.0f, 0.0f };
 
     // Limit gain to -100dB
     assert(gain > 0.00001f);
@@ -90,18 +90,18 @@ void BiquadFilter_setParams(BiquadFilter *filter, BiquadType type, ALfloat gain,
 }
 
 
-void BiquadFilter_processC(BiquadFilter *filter, ALfloat *RESTRICT dst, const ALfloat *RESTRICT src, ALsizei numsamples)
+void BiquadFilter_processC(BiquadFilter *filter, float *RESTRICT dst, const float *RESTRICT src, int numsamples)
 {
-    const ALfloat b0 = filter->b0;
-    const ALfloat b1 = filter->b1;
-    const ALfloat b2 = filter->b2;
-    const ALfloat a1 = filter->a1;
-    const ALfloat a2 = filter->a2;
-    ALfloat z1 = filter->z1;
-    ALfloat z2 = filter->z2;
-
     ASSUME(numsamples > 0);
 
+    const float b0{filter->b0};
+    const float b1{filter->b1};
+    const float b2{filter->b2};
+    const float a1{filter->a1};
+    const float a2{filter->a2};
+    float z1{filter->z1};
+    float z2{filter->z2};
+
     /* Processing loop is Transposed Direct Form II. This requires less storage
      * compared to Direct Form I (only two delay components, instead of a four-
      * sample history; the last two inputs and outputs), and works better for
@@ -110,14 +110,14 @@ void BiquadFilter_processC(BiquadFilter *filter, ALfloat *RESTRICT dst, const AL
      *
      * See: http://www.earlevel.com/main/2003/02/28/biquads/
      */
-    auto proc_sample = [b0,b1,b2,a1,a2,&z1,&z2](ALfloat input) noexcept -> ALfloat
+    auto proc_sample = [b0,b1,b2,a1,a2,&z1,&z2](float input) noexcept -> float
     {
-        ALfloat output = input*b0 + z1;
+        float output = input*b0 + z1;
         z1 = input*b1 - output*a1 + z2;
         z2 = input*b2 - output*a2;
         return output;
     };
-    std::transform<const ALfloat*RESTRICT>(src, src+numsamples, dst, proc_sample);
+    std::transform<const float*RESTRICT>(src, src+numsamples, dst, proc_sample);
 
     filter->z1 = z1;
     filter->z2 = z2;
diff --git a/Alc/filters/splitter.cpp b/Alc/filters/splitter.cpp
index 570f5e2c..d13c8a77 100644
--- a/Alc/filters/splitter.cpp
+++ b/Alc/filters/splitter.cpp
@@ -9,10 +9,10 @@
 #include "math_defs.h"
 
 
-void bandsplit_init(BandSplitter *splitter, ALfloat f0norm)
+void bandsplit_init(BandSplitter *splitter, float f0norm)
 {
-    ALfloat w = f0norm * F_TAU;
-    ALfloat cw = std::cos(w);
+    float w = f0norm * F_TAU;
+    float cw = std::cos(w);
     if(cw > FLT_EPSILON)
         splitter->coeff = (std::sin(w) - 1.0f) / cw;
     else
@@ -30,8 +30,8 @@ void bandsplit_clear(BandSplitter *splitter)
     splitter->hp_z1 = 0.0f;
 }
 
-void bandsplit_process(BandSplitter *splitter, ALfloat *RESTRICT hpout, ALfloat *RESTRICT lpout,
-                       const ALfloat *input, ALsizei count)
+void bandsplit_process(BandSplitter *splitter, float *RESTRICT hpout, float *RESTRICT lpout,
+                       const ALfloat *input, int count)
 {
     ASSUME(count > 0);
 
@@ -67,10 +67,10 @@ void bandsplit_process(BandSplitter *splitter, ALfloat *RESTRICT hpout, ALfloat
 }
 
 
-void splitterap_init(SplitterAllpass *splitter, ALfloat f0norm)
+void splitterap_init(SplitterAllpass *splitter, float f0norm)
 {
-    ALfloat w = f0norm * F_TAU;
-    ALfloat cw = std::cos(w);
+    float w = f0norm * F_TAU;
+    float cw = std::cos(w);
     if(cw > FLT_EPSILON)
         splitter->coeff = (std::sin(w) - 1.0f) / cw;
     else
@@ -84,7 +84,7 @@ void splitterap_clear(SplitterAllpass *splitter)
     splitter->z1 = 0.0f;
 }
 
-void splitterap_process(SplitterAllpass *splitter, ALfloat *RESTRICT samples, ALsizei count)
+void splitterap_process(SplitterAllpass *splitter, float *RESTRICT samples, int count)
 {
     ASSUME(count > 0);
 
diff --git a/Alc/filters/splitter.h b/Alc/filters/splitter.h
index 13f4cd55..96ecdb43 100644
--- a/Alc/filters/splitter.h
+++ b/Alc/filters/splitter.h
@@ -7,35 +7,35 @@
 
 /* Band splitter. Splits a signal into two phase-matching frequency bands. */
 struct BandSplitter {
-    ALfloat coeff{0.0f};
-    ALfloat lp_z1{0.0f};
-    ALfloat lp_z2{0.0f};
-    ALfloat hp_z1{0.0f};
+    float coeff{0.0f};
+    float lp_z1{0.0f};
+    float lp_z2{0.0f};
+    float hp_z1{0.0f};
 };
 
-void bandsplit_init(BandSplitter *splitter, ALfloat f0norm);
+void bandsplit_init(BandSplitter *splitter, float f0norm);
 void bandsplit_clear(BandSplitter *splitter);
-void bandsplit_process(BandSplitter *splitter, ALfloat *RESTRICT hpout, ALfloat *RESTRICT lpout,
-                       const ALfloat *input, ALsizei count);
+void bandsplit_process(BandSplitter *splitter, float *RESTRICT hpout, float *RESTRICT lpout,
+                       const float *input, int count);
 
 /* The all-pass portion of the band splitter. Applies the same phase shift
  * without splitting the signal.
  */
 struct SplitterAllpass {
-    ALfloat coeff{0.0f};
-    ALfloat z1{0.0f};
+    float coeff{0.0f};
+    float z1{0.0f};
 };
 
-void splitterap_init(SplitterAllpass *splitter, ALfloat f0norm);
+void splitterap_init(SplitterAllpass *splitter, float f0norm);
 void splitterap_clear(SplitterAllpass *splitter);
-void splitterap_process(SplitterAllpass *splitter, ALfloat *RESTRICT samples, ALsizei count);
+void splitterap_process(SplitterAllpass *splitter, float *RESTRICT samples, int count);
 
 
 struct FrontStablizer {
     SplitterAllpass APFilter[MAX_OUTPUT_CHANNELS];
     BandSplitter LFilter, RFilter;
-    alignas(16) ALfloat LSplit[2][BUFFERSIZE];
-    alignas(16) ALfloat RSplit[2][BUFFERSIZE];
+    alignas(16) float LSplit[2][BUFFERSIZE];
+    alignas(16) float RSplit[2][BUFFERSIZE];
 
     DEF_NEWDEL(FrontStablizer)
 };