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Whitespace and intentation tidy

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This commit is contained in:
Ross Owen
2013-11-28 12:02:07 +00:00
parent 5f70b9a002
commit 17e668b33d
1 changed files with 83 additions and 107 deletions
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190
module_usb_audio/audio.xc
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@@ -169,7 +169,6 @@ static inline void doI2SClocks(unsigned divide)
unsigned dsdSample_l = 0x96960000;
unsigned dsdSample_r = 0x96960000;
#endif
int counter = 0;
unsigned underflowWord = 0;
#if NUM_USB_CHAN_IN > 0
@@ -364,7 +363,6 @@ static inline void doI2SClocks(unsigned divide)
while (1)
{
outuint(c_out, 0);
/* Check for sample freq change (or other command) or new samples from mixer*/
if(testct(c_out))
@@ -391,7 +389,6 @@ static inline void doI2SClocks(unsigned divide)
{
#ifndef MIXER // Interfaces straight to decouple()
underflow = inuint(c_out);
counter++;
#if NUM_USB_CHAN_IN > 0
#pragma loop unroll
for(int i = 0; i < NUM_USB_CHAN_IN; i++)
@@ -418,7 +415,7 @@ static inline void doI2SClocks(unsigned divide)
}
}
#endif
#else
#else /* ifndef MIXER */
#pragma loop unroll
for(int i = 0; i < NUM_USB_CHAN_OUT; i++)
{
@@ -463,13 +460,13 @@ static inline void doI2SClocks(unsigned divide)
tmp = 0;
#if (DSD_CHANS_DAC != 0) && (NUM_USB_CHAN_OUT > 0)
if(dsdMode == DSD_MODE_NATIVE)
{
/* 8 bits per chan, 1st 1-bit sample in MSB */
dsdSample_l = samplesOut[0];
dsdSample_r = samplesOut[1];
dsdSample_r = bitrev(byterev(dsdSample_r));
dsdSample_l = bitrev(byterev(dsdSample_l));
if(dsdMode == DSD_MODE_NATIVE)
{
/* 8 bits per chan, 1st 1-bit sample in MSB */
dsdSample_l = samplesOut[0];
dsdSample_r = samplesOut[1];
dsdSample_r = bitrev(byterev(dsdSample_r));
dsdSample_l = bitrev(byterev(dsdSample_l));
switch (divide)
{
@@ -516,168 +513,149 @@ static inline void doI2SClocks(unsigned divide)
break;
}
}
else if(dsdMode == DSD_MODE_DOP)
{
if(!everyOther)
}
else if(dsdMode == DSD_MODE_DOP)
{
dsdSample_l = ((samplesOut[0] & 0xffff00) << 8);
dsdSample_r = ((samplesOut[1] & 0xffff00) << 8);
if(!everyOther)
{
dsdSample_l = ((samplesOut[0] & 0xffff00) << 8);
dsdSample_r = ((samplesOut[1] & 0xffff00) << 8);
everyOther = 1;
everyOther = 1;
switch (divide)
{
case 8:
switch (divide)
{
case 8:
p_dsd_clk <: 0xF0F0F0F0;
p_dsd_clk <: 0xF0F0F0F0;
p_dsd_clk <: 0xF0F0F0F0;
p_dsd_clk <: 0xF0F0F0F0;
break;
case 4:
case 4:
p_dsd_clk <: 0xCCCCCCCC;
p_dsd_clk <: 0xCCCCCCCC;
break;
case 2:
case 2:
p_dsd_clk <: 0xAAAAAAAA;
break;
case 1:
break;
}
}
else if(everyOther)
{
everyOther = 0;
dsdSample_l = dsdSample_l | ((samplesOut[0] & 0xffff00) >> 8);
dsdSample_r = dsdSample_r | ((samplesOut[1] & 0xffff00) >> 8);
// Output 16 clocks DSD to all
//p_dsd_dac[0] <: bitrev(dsdSample_l);
//p_dsd_dac[1] <: bitrev(dsdSample_r);
asm volatile("out res[%0], %1"::"r"(p_dsd_dac[0]),"r"(bitrev(dsdSample_l)));
asm volatile("out res[%0], %1"::"r"(p_dsd_dac[1]),"r"(bitrev(dsdSample_r)));
switch (divide)
}
}
else // everyOther
{
case 8:
everyOther = 0;
dsdSample_l = dsdSample_l | ((samplesOut[0] & 0xffff00) >> 8);
dsdSample_r = dsdSample_r | ((samplesOut[1] & 0xffff00) >> 8);
// Output 16 clocks DSD to all
//p_dsd_dac[0] <: bitrev(dsdSample_l);
//p_dsd_dac[1] <: bitrev(dsdSample_r);
asm volatile("out res[%0], %1"::"r"(p_dsd_dac[0]),"r"(bitrev(dsdSample_l)));
asm volatile("out res[%0], %1"::"r"(p_dsd_dac[1]),"r"(bitrev(dsdSample_r)));
switch (divide)
{
case 8:
p_dsd_clk <: 0xF0F0F0F0;
p_dsd_clk <: 0xF0F0F0F0;
p_dsd_clk <: 0xF0F0F0F0;
p_dsd_clk <: 0xF0F0F0F0;
break;
case 4:
case 4:
p_dsd_clk <: 0xCCCCCCCC;
p_dsd_clk <: 0xCCCCCCCC;
break;
case 2:
case 2:
p_dsd_clk <: 0xAAAAAAAA;
break;
case 1:
break;
}
}
}
}
}
else
else
#endif
{
{
#pragma xta endpoint "i2s_output_l"
#if (I2S_CHANS_DAC != 0) && (NUM_USB_CHAN_OUT != 0)
#pragma loop unroll
for(int i = 0; i < I2S_CHANS_DAC; i+=2)
{
p_i2s_dac[tmp++] <: bitrev(samplesOut[i]); /* Output LEFT sample to DAC */
}
for(int i = 0; i < I2S_CHANS_DAC; i+=2)
{
p_i2s_dac[tmp++] <: bitrev(samplesOut[i]); /* Output LEFT sample to DAC */
}
#endif
#ifndef CODEC_MASTER
/* LR clock delayed by one clock, This is so MSB is output on the falling edge of BCLK
* after the falling edge on which LRCLK was toggled. (see I2S spec) */
/* Generate clocks LR Clock low - LEFT */
p_lrclk <: 0x80000000;
doI2SClocks(divide);
/* LR clock delayed by one clock, This is so MSB is output on the falling edge of BCLK
* after the falling edge on which LRCLK was toggled. (see I2S spec) */
/* Generate clocks LR Clock low - LEFT */
p_lrclk <: 0x80000000;
doI2SClocks(divide);
#endif
#if (I2S_CHANS_ADC != 0)
/* Input prevous R sample into R in buffer */
index = 0;
/* Input prevous R sample into R in buffer */
index = 0;
#pragma loop unroll
for(int i = 1; i < I2S_CHANS_ADC; i += 2)
{
p_i2s_adc[index++] :> sample;
for(int i = 1; i < I2S_CHANS_ADC; i += 2)
{
p_i2s_adc[index++] :> sample;
#if NUM_USB_CHAN_IN > 0
samplesIn[i] = bitrev(sample);
samplesIn[i] = bitrev(sample);
/* Store the previous left in left */
samplesIn[i-1] = samplesInPrev[i];
/* Store the previous left in left */
samplesIn[i-1] = samplesInPrev[i];
#endif
}
}
#endif
#if defined(SPDIF) && (NUM_USB_CHAN_OUT > 0)
outuint(c_spd_out, samplesOut[SPDIF_TX_INDEX]); /* Forward sample to S/PDIF Tx thread */
sample = samplesOut[SPDIF_TX_INDEX + 1];
outuint(c_spd_out, sample); /* Forward sample to S/PDIF Tx thread */
#ifdef RAMP_CHECK
sample >>= 8;
if (started<10000) {
if (sample == prev+1)
started++;
}
else
if (sample != prev+1 && sample != 0) {
printintln(prev);
printintln(sample);
printintln(prev-sample+1);
}
prev = sample;
#endif
outuint(c_spd_out, samplesOut[SPDIF_TX_INDEX]); /* Forward sample to S/PDIF Tx thread */
sample = samplesOut[SPDIF_TX_INDEX + 1];
outuint(c_spd_out, sample); /* Forward sample to S/PDIF Tx thread */
#endif
tmp = 0;
tmp = 0;
#pragma xta endpoint "i2s_output_r"
#if (I2S_CHANS_DAC != 0) && (NUM_USB_CHAN_OUT != 0)
#pragma loop unroll
for(int i = 1; i < I2S_CHANS_DAC; i+=2)
{
p_i2s_dac[tmp++] <: bitrev(samplesOut[i]); /* Output RIGHT sample to DAC */
}
for(int i = 1; i < I2S_CHANS_DAC; i+=2)
{
p_i2s_dac[tmp++] <: bitrev(samplesOut[i]); /* Output RIGHT sample to DAC */
}
#endif
#ifndef CODEC_MASTER
/* Clock out data (and LR clock) */
p_lrclk <: 0x7FFFFFFF;
doI2SClocks(divide);
/* Clock out data (and LR clock) */
p_lrclk <: 0x7FFFFFFF;
doI2SClocks(divide);
#endif
#if (I2S_CHANS_ADC != 0)
/* Input previous L ADC sample */
index = 0;
/* Input previous L ADC sample */
index = 0;
#pragma loop unroll
for(int i = 1; i < I2S_CHANS_ADC; i += 2)
{
p_i2s_adc[index++] :> sample;
for(int i = 1; i < I2S_CHANS_ADC; i += 2)
{
p_i2s_adc[index++] :> sample;
#if NUM_USB_CHAN_IN > 0
samplesInPrev[i] = bitrev(sample);
samplesInPrev[i] = bitrev(sample);
#endif
}
}
#ifdef SU1_ADC_ENABLE
{
unsigned x;
{
unsigned x;
x = inuint(c_adc);
inct(c_adc);
asm("stw %0, dp[g_adcVal]"::"r"(x));
}
x = inuint(c_adc);
inct(c_adc);
asm("stw %0, dp[g_adcVal]"::"r"(x));
}
#endif
#endif
@@ -726,9 +704,7 @@ static inline void doI2SClocks(unsigned divide)
}
}
}
#endif
}
return {0,0};
}