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Bring that Whole New World to the Old Continent too

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Applies the clang-format style to the 2.1 branch as done for master in
5dbf1809c6.
This commit is contained in:
Rémi Verschelde
2017-03-19 00:36:26 +01:00
parent 1d418afe86
commit f8db8a3faa
1308 changed files with 147754 additions and 174357 deletions
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321
servers/audio/audio_rb_resampler.cpp
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@@ -28,7 +28,6 @@
/*************************************************************************/
#include "audio_rb_resampler.h"
int AudioRBResampler::get_channel_count() const {
if (!rb)
@@ -37,153 +36,142 @@ int AudioRBResampler::get_channel_count() const {
return channels;
}
template <int C>
uint32_t AudioRBResampler::_resample(int32_t *p_dest, int p_todo, int32_t p_increment) {
template<int C>
uint32_t AudioRBResampler::_resample(int32_t *p_dest,int p_todo,int32_t p_increment) {
uint32_t read = offset & MIX_FRAC_MASK;
uint32_t read=offset&MIX_FRAC_MASK;
for (int i = 0; i < p_todo; i++) {
for (int i=0;i<p_todo;i++) {
offset = (offset + p_increment)&(((1<<(rb_bits+MIX_FRAC_BITS))-1));
read+=p_increment;
offset = (offset + p_increment) & (((1 << (rb_bits + MIX_FRAC_BITS)) - 1));
read += p_increment;
uint32_t pos = offset >> MIX_FRAC_BITS;
uint32_t frac = offset & MIX_FRAC_MASK;
#ifndef FAST_AUDIO
ERR_FAIL_COND_V(pos>=rb_len,0);
ERR_FAIL_COND_V(pos >= rb_len, 0);
#endif
uint32_t pos_next = (pos+1)&rb_mask;
uint32_t pos_next = (pos + 1) & rb_mask;
//printf("rb pos %i\n",pos);
// since this is a template with a known compile time value (C), conditionals go away when compiling.
if (C==1) {
if (C == 1) {
int32_t v0 = rb[pos];
int32_t v0n=rb[pos_next];
int32_t v0n = rb[pos_next];
#ifndef FAST_AUDIO
v0+=(v0n-v0)*(int32_t)frac >> MIX_FRAC_BITS;
v0 += (v0n - v0) * (int32_t)frac >> MIX_FRAC_BITS;
#endif
v0<<=16;
p_dest[i]=v0;
v0 <<= 16;
p_dest[i] = v0;
}
if (C==2) {
if (C == 2) {
int32_t v0 = rb[(pos<<1)+0];
int32_t v1 = rb[(pos<<1)+1];
int32_t v0n=rb[(pos_next<<1)+0];
int32_t v1n=rb[(pos_next<<1)+1];
int32_t v0 = rb[(pos << 1) + 0];
int32_t v1 = rb[(pos << 1) + 1];
int32_t v0n = rb[(pos_next << 1) + 0];
int32_t v1n = rb[(pos_next << 1) + 1];
#ifndef FAST_AUDIO
v0+=(v0n-v0)*(int32_t)frac >> MIX_FRAC_BITS;
v1+=(v1n-v1)*(int32_t)frac >> MIX_FRAC_BITS;
v0 += (v0n - v0) * (int32_t)frac >> MIX_FRAC_BITS;
v1 += (v1n - v1) * (int32_t)frac >> MIX_FRAC_BITS;
#endif
v0<<=16;
v1<<=16;
p_dest[(i<<1)+0]=v0;
p_dest[(i<<1)+1]=v1;
v0 <<= 16;
v1 <<= 16;
p_dest[(i << 1) + 0] = v0;
p_dest[(i << 1) + 1] = v1;
}
if (C==4) {
if (C == 4) {
int32_t v0 = rb[(pos<<2)+0];
int32_t v1 = rb[(pos<<2)+1];
int32_t v2 = rb[(pos<<2)+2];
int32_t v3 = rb[(pos<<2)+3];
int32_t v0n = rb[(pos_next<<2)+0];
int32_t v1n=rb[(pos_next<<2)+1];
int32_t v2n=rb[(pos_next<<2)+2];
int32_t v3n=rb[(pos_next<<2)+3];
int32_t v0 = rb[(pos << 2) + 0];
int32_t v1 = rb[(pos << 2) + 1];
int32_t v2 = rb[(pos << 2) + 2];
int32_t v3 = rb[(pos << 2) + 3];
int32_t v0n = rb[(pos_next << 2) + 0];
int32_t v1n = rb[(pos_next << 2) + 1];
int32_t v2n = rb[(pos_next << 2) + 2];
int32_t v3n = rb[(pos_next << 2) + 3];
#ifndef FAST_AUDIO
v0+=(v0n-v0)*(int32_t)frac >> MIX_FRAC_BITS;
v1+=(v1n-v1)*(int32_t)frac >> MIX_FRAC_BITS;
v2+=(v2n-v2)*(int32_t)frac >> MIX_FRAC_BITS;
v3+=(v3n-v3)*(int32_t)frac >> MIX_FRAC_BITS;
v0 += (v0n - v0) * (int32_t)frac >> MIX_FRAC_BITS;
v1 += (v1n - v1) * (int32_t)frac >> MIX_FRAC_BITS;
v2 += (v2n - v2) * (int32_t)frac >> MIX_FRAC_BITS;
v3 += (v3n - v3) * (int32_t)frac >> MIX_FRAC_BITS;
#endif
v0<<=16;
v1<<=16;
v2<<=16;
v3<<=16;
p_dest[(i<<2)+0]=v0;
p_dest[(i<<2)+1]=v1;
p_dest[(i<<2)+2]=v2;
p_dest[(i<<2)+3]=v3;
v0 <<= 16;
v1 <<= 16;
v2 <<= 16;
v3 <<= 16;
p_dest[(i << 2) + 0] = v0;
p_dest[(i << 2) + 1] = v1;
p_dest[(i << 2) + 2] = v2;
p_dest[(i << 2) + 3] = v3;
}
if (C==6) {
if (C == 6) {
int32_t v0 = rb[(pos*6)+0];
int32_t v1 = rb[(pos*6)+1];
int32_t v2 = rb[(pos*6)+2];
int32_t v3 = rb[(pos*6)+3];
int32_t v4 = rb[(pos*6)+4];
int32_t v5 = rb[(pos*6)+5];
int32_t v0n = rb[(pos_next*6)+0];
int32_t v1n=rb[(pos_next*6)+1];
int32_t v2n=rb[(pos_next*6)+2];
int32_t v3n=rb[(pos_next*6)+3];
int32_t v4n=rb[(pos_next*6)+4];
int32_t v5n=rb[(pos_next*6)+5];
int32_t v0 = rb[(pos * 6) + 0];
int32_t v1 = rb[(pos * 6) + 1];
int32_t v2 = rb[(pos * 6) + 2];
int32_t v3 = rb[(pos * 6) + 3];
int32_t v4 = rb[(pos * 6) + 4];
int32_t v5 = rb[(pos * 6) + 5];
int32_t v0n = rb[(pos_next * 6) + 0];
int32_t v1n = rb[(pos_next * 6) + 1];
int32_t v2n = rb[(pos_next * 6) + 2];
int32_t v3n = rb[(pos_next * 6) + 3];
int32_t v4n = rb[(pos_next * 6) + 4];
int32_t v5n = rb[(pos_next * 6) + 5];
#ifndef FAST_AUDIO
v0+=(v0n-v0)*(int32_t)frac >> MIX_FRAC_BITS;
v1+=(v1n-v1)*(int32_t)frac >> MIX_FRAC_BITS;
v2+=(v2n-v2)*(int32_t)frac >> MIX_FRAC_BITS;
v3+=(v3n-v3)*(int32_t)frac >> MIX_FRAC_BITS;
v4+=(v4n-v4)*(int32_t)frac >> MIX_FRAC_BITS;
v5+=(v5n-v5)*(int32_t)frac >> MIX_FRAC_BITS;
v0 += (v0n - v0) * (int32_t)frac >> MIX_FRAC_BITS;
v1 += (v1n - v1) * (int32_t)frac >> MIX_FRAC_BITS;
v2 += (v2n - v2) * (int32_t)frac >> MIX_FRAC_BITS;
v3 += (v3n - v3) * (int32_t)frac >> MIX_FRAC_BITS;
v4 += (v4n - v4) * (int32_t)frac >> MIX_FRAC_BITS;
v5 += (v5n - v5) * (int32_t)frac >> MIX_FRAC_BITS;
#endif
v0<<=16;
v1<<=16;
v2<<=16;
v3<<=16;
v4<<=16;
v5<<=16;
p_dest[(i*6)+0]=v0;
p_dest[(i*6)+1]=v1;
p_dest[(i*6)+2]=v2;
p_dest[(i*6)+3]=v3;
p_dest[(i*6)+4]=v4;
p_dest[(i*6)+5]=v5;
v0 <<= 16;
v1 <<= 16;
v2 <<= 16;
v3 <<= 16;
v4 <<= 16;
v5 <<= 16;
p_dest[(i * 6) + 0] = v0;
p_dest[(i * 6) + 1] = v1;
p_dest[(i * 6) + 2] = v2;
p_dest[(i * 6) + 3] = v3;
p_dest[(i * 6) + 4] = v4;
p_dest[(i * 6) + 5] = v5;
}
}
return read>>MIX_FRAC_BITS;//rb_read_pos=offset>>MIX_FRAC_BITS;
return read >> MIX_FRAC_BITS; //rb_read_pos=offset>>MIX_FRAC_BITS;
}
bool AudioRBResampler::mix(int32_t *p_dest, int p_frames) {
if (!rb)
return false;
int write_pos_cache=rb_write_pos;
int write_pos_cache = rb_write_pos;
int32_t increment=(src_mix_rate*MIX_FRAC_LEN)/target_mix_rate;
int32_t increment = (src_mix_rate * MIX_FRAC_LEN) / target_mix_rate;
int rb_todo;
if (write_pos_cache==rb_read_pos) {
if (write_pos_cache == rb_read_pos) {
return false; //out of buffer
} else if (rb_read_pos<write_pos_cache) {
} else if (rb_read_pos < write_pos_cache) {
rb_todo=write_pos_cache-rb_read_pos; //-1?
rb_todo = write_pos_cache - rb_read_pos; //-1?
} else {
rb_todo=(rb_len-rb_read_pos)+write_pos_cache; //-1?
rb_todo = (rb_len - rb_read_pos) + write_pos_cache; //-1?
}
int todo = MIN( ((int64_t(rb_todo)<<MIX_FRAC_BITS)/increment)+1, p_frames );
int todo = MIN(((int64_t(rb_todo) << MIX_FRAC_BITS) / increment) + 1, p_frames);
#if 0
if (int(src_mix_rate)==target_mix_rate) {
@@ -224,118 +212,104 @@ bool AudioRBResampler::mix(int32_t *p_dest, int p_frames) {
#endif
{
uint32_t read=0;
switch(channels) {
case 1: read=_resample<1>(p_dest,todo,increment); break;
case 2: read=_resample<2>(p_dest,todo,increment); break;
case 4: read=_resample<4>(p_dest,todo,increment); break;
case 6: read=_resample<6>(p_dest,todo,increment); break;
uint32_t read = 0;
switch (channels) {
case 1: read = _resample<1>(p_dest, todo, increment); break;
case 2: read = _resample<2>(p_dest, todo, increment); break;
case 4: read = _resample<4>(p_dest, todo, increment); break;
case 6: read = _resample<6>(p_dest, todo, increment); break;
}
#if 1
//end of stream, fadeout
int remaining = p_frames-todo;
if (remaining && todo>0) {
int remaining = p_frames - todo;
if (remaining && todo > 0) {
//print_line("fadeout");
for(int c=0;c<channels;c++) {
for (int c = 0; c < channels; c++) {
for(int i=0;i<todo;i++) {
for (int i = 0; i < todo; i++) {
int32_t samp = p_dest[i*channels+c]>>8;
uint32_t mul = (todo-i) * 256 /todo;
int32_t samp = p_dest[i * channels + c] >> 8;
uint32_t mul = (todo - i) * 256 / todo;
//print_line("mul: "+itos(i)+" "+itos(mul));
p_dest[i*channels+c]=samp*mul;
p_dest[i * channels + c] = samp * mul;
}
}
}
#else
int remaining = p_frames-todo;
if (remaining && todo>0) {
int remaining = p_frames - todo;
if (remaining && todo > 0) {
for (int c = 0; c < channels; c++) {
for(int c=0;c<channels;c++) {
int32_t from = p_dest[(todo - 1) * channels + c] >> 8;
int32_t from = p_dest[(todo-1)*channels+c]>>8;
for (int i = 0; i < remaining; i++) {
for(int i=0;i<remaining;i++) {
uint32_t mul = (remaining-i) * 256 /remaining;
p_dest[(todo+i)*channels+c]=from*mul;
uint32_t mul = (remaining - i) * 256 / remaining;
p_dest[(todo + i) * channels + c] = from * mul;
}
}
}
#endif
//zero out what remains there to avoid glitches
for(int i=todo*channels;i<int(p_frames)*channels;i++) {
for (int i = todo * channels; i < int(p_frames) * channels; i++) {
p_dest[i]=0;
p_dest[i] = 0;
}
if (read>rb_todo)
read=rb_todo;
rb_read_pos = (rb_read_pos+read)&rb_mask;
if (read > rb_todo)
read = rb_todo;
rb_read_pos = (rb_read_pos + read) & rb_mask;
}
return true;
}
Error AudioRBResampler::setup(int p_channels, int p_src_mix_rate, int p_target_mix_rate, int p_buffer_msec, int p_minbuff_needed) {
Error AudioRBResampler::setup(int p_channels,int p_src_mix_rate,int p_target_mix_rate,int p_buffer_msec,int p_minbuff_needed) {
ERR_FAIL_COND_V(p_channels!=1 && p_channels!=2 && p_channels!=4 && p_channels!=6,ERR_INVALID_PARAMETER);
ERR_FAIL_COND_V(p_channels != 1 && p_channels != 2 && p_channels != 4 && p_channels != 6, ERR_INVALID_PARAMETER);
//float buffering_sec = int(GLOBAL_DEF("audio/stream_buffering_ms",500))/1000.0;
int desired_rb_bits =nearest_shift(MAX((p_buffer_msec/1000.0)*p_src_mix_rate,p_minbuff_needed));
int desired_rb_bits = nearest_shift(MAX((p_buffer_msec / 1000.0) * p_src_mix_rate, p_minbuff_needed));
bool recreate=!rb;
bool recreate = !rb;
if (rb && (uint32_t(desired_rb_bits)!=rb_bits || channels!=uint32_t(p_channels))) {
if (rb && (uint32_t(desired_rb_bits) != rb_bits || channels != uint32_t(p_channels))) {
//recreate
memdelete_arr(rb);
memdelete_arr(read_buf);
recreate=true;
recreate = true;
}
if (recreate) {
channels=p_channels;
rb_bits=desired_rb_bits;
rb_len=(1<<rb_bits);
rb_mask=rb_len-1;
rb = memnew_arr( int16_t, rb_len * p_channels );
read_buf = memnew_arr( int16_t, rb_len * p_channels );
channels = p_channels;
rb_bits = desired_rb_bits;
rb_len = (1 << rb_bits);
rb_mask = rb_len - 1;
rb = memnew_arr(int16_t, rb_len * p_channels);
read_buf = memnew_arr(int16_t, rb_len * p_channels);
}
src_mix_rate=p_src_mix_rate;
target_mix_rate=p_target_mix_rate;
offset=0;
rb_read_pos=0;
rb_write_pos=0;
src_mix_rate = p_src_mix_rate;
target_mix_rate = p_target_mix_rate;
offset = 0;
rb_read_pos = 0;
rb_write_pos = 0;
//avoid maybe strange noises upon load
for (int i=0;i<(rb_len*channels);i++) {
for (int i = 0; i < (rb_len * channels); i++) {
rb[i]=0;
read_buf[i]=0;
rb[i] = 0;
read_buf[i] = 0;
}
return OK;
}
void AudioRBResampler::clear() {
@@ -348,29 +322,28 @@ void AudioRBResampler::clear() {
memdelete_arr(rb);
memdelete_arr(read_buf);
}
rb=NULL;
offset=0;
rb_read_pos=0;
rb_write_pos=0;
read_buf=NULL;
rb = NULL;
offset = 0;
rb_read_pos = 0;
rb_write_pos = 0;
read_buf = NULL;
}
AudioRBResampler::AudioRBResampler() {
rb=NULL;
offset=0;
read_buf=NULL;
rb_read_pos=0;
rb_write_pos=0;
rb_bits=0;
rb_len=0;
rb_mask=0;
read_buff_len=0;
channels=0;
src_mix_rate=0;
target_mix_rate=0;
rb = NULL;
offset = 0;
read_buf = NULL;
rb_read_pos = 0;
rb_write_pos = 0;
rb_bits = 0;
rb_len = 0;
rb_mask = 0;
read_buff_len = 0;
channels = 0;
src_mix_rate = 0;
target_mix_rate = 0;
}
AudioRBResampler::~AudioRBResampler() {
@@ -379,6 +352,4 @@ AudioRBResampler::~AudioRBResampler() {
memdelete_arr(rb);
memdelete_arr(read_buf);
}
}