kolibrios/programs/develop/libraries/libmpg123/sample.h

/*
	sample.h: The conversion from internal data to output samples of differing formats.

	copyright 2007-9 by the mpg123 project - free software under the terms of the LGPL 2.1
	see COPYING and AUTHORS files in distribution or http://mpg123.org
	initially written by Thomas Orgis, taking WRITE_SAMPLE from decode.c
	Later added the end-conversion specific macros here, too.
*/

#ifndef SAMPLE_H
#define SAMPLE_H

/* mpg123lib_intern.h is included already, right? */

/* Special case is fixed point math... which does work, but not that nice yet.  */
#ifdef REAL_IS_FIXED
static inline short idiv_signed_rounded(long x, int shift)
{
	x >>= (shift - 1);
	x += (x & 1);
	return (short)(x >> 1);
}
#  define REAL_PLUS_32767       ( 32767 << 15 )
#  define REAL_MINUS_32768      ( -32768 << 15 )
#  define REAL_TO_SHORT(x)      (idiv_signed_rounded(x, 15))
/* No better code (yet).  */
#  define REAL_TO_SHORT_ACCURATE(x) REAL_TO_SHORT(x)
/* This is just here for completeness, it is not used! */
# define REAL_TO_S32(x)        (x)
#endif

/* From now on for single precision float... double precision is a possible option once we added some bits. But, it would be rather insane. */
#ifndef REAL_TO_SHORT

/* Define the accurate rounding function. */
# if (defined REAL_IS_FLOAT) && (defined IEEE_FLOAT)
/* This function is only available for IEEE754 single-precision values
   This is nearly identical to proper rounding, just -+0.5 is rounded to 0 */
static inline short ftoi16(float x)
{
	union
	{
		float f;
		int32_t i;
	} u_fi;
	u_fi.f = x + 12582912.0f; /* Magic Number: 2^23 + 2^22 */
	return (short)u_fi.i;
}
#  define REAL_TO_SHORT_ACCURATE(x)      ftoi16(x)
# else
/* The "proper" rounding, plain C, a bit slow. */
#  define REAL_TO_SHORT_ACCURATE(x)      (short)((x)>0.0?(x)+0.5:(x)-0.5)
# endif

/* Now define the normal rounding. */
# ifdef ACCURATE_ROUNDING
#  define REAL_TO_SHORT(x)      REAL_TO_SHORT_ACCURATE(x)
# else
/* Non-accurate rounding... simple truncation. Fastest, most LSB errors. */
#  define REAL_TO_SHORT(x)      (short)(x)
# endif

#endif /* REAL_TO_SHORT */

/* We should add dithering for S32, too? */
#ifndef REAL_TO_S32
# ifdef ACCURATE_ROUNDING
#  define REAL_TO_S32(x) (int32_t)((x)>0.0?(x)+0.5:(x)-0.5)
# else
#  define REAL_TO_S32(x) (int32_t)(x)
# endif
#endif

#ifndef REAL_PLUS_32767
# define REAL_PLUS_32767 32767.0
#endif
#ifndef REAL_MINUS_32768
# define REAL_MINUS_32768 -32768.0
#endif
#ifndef REAL_PLUS_S32
# define REAL_PLUS_S32 2147483647.0
#endif
#ifndef REAL_MINUS_S32
# define REAL_MINUS_S32 -2147483648.0
#endif


/* The actual storage of a decoded sample is separated in the following macros.
   We can handle different types, we could also handle dithering here. */

/* Macro to produce a short (signed 16bit) output sample from internal representation,
   which may be float, double or indeed some integer for fixed point handling. */
#define WRITE_SHORT_SAMPLE(samples,sum,clip) \
  if( (sum) > REAL_PLUS_32767) { *(samples) = 0x7fff; (clip)++; } \
  else if( (sum) < REAL_MINUS_32768) { *(samples) = -0x8000; (clip)++; } \
  else { *(samples) = REAL_TO_SHORT(sum); }

/* Same as above, but always using accurate rounding. Would we want softer clipping here, too? */
#define WRITE_SHORT_SAMPLE_ACCURATE(samples,sum,clip) \
  if( (sum) > REAL_PLUS_32767) { *(samples) = 0x7fff; (clip)++; } \
  else if( (sum) < REAL_MINUS_32768) { *(samples) = -0x8000; (clip)++; } \
  else { *(samples) = REAL_TO_SHORT_ACCURATE(sum); }

/*
	32bit signed 
	We do clipping with the same old borders... but different conversion.
	We see here that we need extra work for non-16bit output... we optimized for 16bit.
	-0x7fffffff-1 is the minimum 32 bit signed integer value expressed so that MSVC 
	does not give a compile time warning.
*/
#define WRITE_S32_SAMPLE(samples,sum,clip) \
	{ \
		real tmpsum = REAL_MUL((sum),S32_RESCALE); \
		if( tmpsum > REAL_PLUS_S32 ){ *(samples) = 0x7fffffff; (clip)++; } \
		else if( tmpsum < REAL_MINUS_S32 ) { *(samples) = -0x7fffffff-1; (clip)++; } \
		else { *(samples) = REAL_TO_S32(tmpsum); } \
	}

/* Produce an 8bit sample, via 16bit intermediate. */
#define WRITE_8BIT_SAMPLE(samples,sum,clip) \
{ \
	short write_8bit_tmp; \
	if( (sum) > REAL_PLUS_32767) { write_8bit_tmp = 0x7fff; (clip)++; } \
	else if( (sum) < REAL_MINUS_32768) { write_8bit_tmp = -0x8000; (clip)++; } \
	else { write_8bit_tmp = REAL_TO_SHORT(sum); } \
	*(samples) = fr->conv16to8[write_8bit_tmp>>AUSHIFT]; \
}
#ifndef REAL_IS_FIXED
#define WRITE_REAL_SAMPLE(samples,sum,clip) *(samples) = ((real)1./SHORT_SCALE)*(sum)
#endif

#endif
libmpg123 1.9.0 git-svn-id: svn://kolibrios.org@1905 a494cfbc-eb01-0410-851d-a64ba20cac60 2011-03-11 11:57:03 +01:00			`/*`
			`sample.h: The conversion from internal data to output samples of differing formats.`

			`copyright 2007-9 by the mpg123 project - free software under the terms of the LGPL 2.1`
			`see COPYING and AUTHORS files in distribution or http://mpg123.org`
			`initially written by Thomas Orgis, taking WRITE_SAMPLE from decode.c`
			`Later added the end-conversion specific macros here, too.`
			`*/`

			`#ifndef SAMPLE_H`
			`#define SAMPLE_H`

			`/* mpg123lib_intern.h is included already, right? */`

			`/* Special case is fixed point math... which does work, but not that nice yet. */`
			`#ifdef REAL_IS_FIXED`
			`static inline short idiv_signed_rounded(long x, int shift)`
			`{`
			`x >>= (shift - 1);`
			`x += (x & 1);`
			`return (short)(x >> 1);`
			`}`
			`# define REAL_PLUS_32767 ( 32767 << 15 )`
			`# define REAL_MINUS_32768 ( -32768 << 15 )`
			`# define REAL_TO_SHORT(x) (idiv_signed_rounded(x, 15))`
			`/* No better code (yet). */`
			`# define REAL_TO_SHORT_ACCURATE(x) REAL_TO_SHORT(x)`
			`/* This is just here for completeness, it is not used! */`
			`# define REAL_TO_S32(x) (x)`
			`#endif`

			`/* From now on for single precision float... double precision is a possible option once we added some bits. But, it would be rather insane. */`
			`#ifndef REAL_TO_SHORT`

			`/* Define the accurate rounding function. */`
			`# if (defined REAL_IS_FLOAT) && (defined IEEE_FLOAT)`
			`/* This function is only available for IEEE754 single-precision values`
			`This is nearly identical to proper rounding, just -+0.5 is rounded to 0 */`
			`static inline short ftoi16(float x)`
			`{`
			`union`
			`{`
			`float f;`
			`int32_t i;`
			`} u_fi;`
			`u_fi.f = x + 12582912.0f; /* Magic Number: 2^23 + 2^22 */`
			`return (short)u_fi.i;`
			`}`
			`# define REAL_TO_SHORT_ACCURATE(x) ftoi16(x)`
			`# else`
			`/* The "proper" rounding, plain C, a bit slow. */`
			`# define REAL_TO_SHORT_ACCURATE(x) (short)((x)>0.0?(x)+0.5:(x)-0.5)`
			`# endif`

			`/* Now define the normal rounding. */`
			`# ifdef ACCURATE_ROUNDING`
			`# define REAL_TO_SHORT(x) REAL_TO_SHORT_ACCURATE(x)`
			`# else`
			`/* Non-accurate rounding... simple truncation. Fastest, most LSB errors. */`
			`# define REAL_TO_SHORT(x) (short)(x)`
			`# endif`

			`#endif /* REAL_TO_SHORT */`

			`/* We should add dithering for S32, too? */`
			`#ifndef REAL_TO_S32`
			`# ifdef ACCURATE_ROUNDING`
			`# define REAL_TO_S32(x) (int32_t)((x)>0.0?(x)+0.5:(x)-0.5)`
			`# else`
			`# define REAL_TO_S32(x) (int32_t)(x)`
			`# endif`
			`#endif`

			`#ifndef REAL_PLUS_32767`
			`# define REAL_PLUS_32767 32767.0`
			`#endif`
			`#ifndef REAL_MINUS_32768`
			`# define REAL_MINUS_32768 -32768.0`
			`#endif`
			`#ifndef REAL_PLUS_S32`
			`# define REAL_PLUS_S32 2147483647.0`
			`#endif`
			`#ifndef REAL_MINUS_S32`
			`# define REAL_MINUS_S32 -2147483648.0`
			`#endif`


			`/* The actual storage of a decoded sample is separated in the following macros.`
			`We can handle different types, we could also handle dithering here. */`

			`/* Macro to produce a short (signed 16bit) output sample from internal representation,`
			`which may be float, double or indeed some integer for fixed point handling. */`
			`#define WRITE_SHORT_SAMPLE(samples,sum,clip) \`
			`if( (sum) > REAL_PLUS_32767) { *(samples) = 0x7fff; (clip)++; } \`
			`else if( (sum) < REAL_MINUS_32768) { *(samples) = -0x8000; (clip)++; } \`
			`else { *(samples) = REAL_TO_SHORT(sum); }`

			`/* Same as above, but always using accurate rounding. Would we want softer clipping here, too? */`
			`#define WRITE_SHORT_SAMPLE_ACCURATE(samples,sum,clip) \`
			`if( (sum) > REAL_PLUS_32767) { *(samples) = 0x7fff; (clip)++; } \`
			`else if( (sum) < REAL_MINUS_32768) { *(samples) = -0x8000; (clip)++; } \`
			`else { *(samples) = REAL_TO_SHORT_ACCURATE(sum); }`

			`/*`
			`32bit signed`
			`We do clipping with the same old borders... but different conversion.`
			`We see here that we need extra work for non-16bit output... we optimized for 16bit.`
			`-0x7fffffff-1 is the minimum 32 bit signed integer value expressed so that MSVC`
			`does not give a compile time warning.`
			`*/`
			`#define WRITE_S32_SAMPLE(samples,sum,clip) \`
			`{ \`
			`real tmpsum = REAL_MUL((sum),S32_RESCALE); \`
			`if( tmpsum > REAL_PLUS_S32 ){ *(samples) = 0x7fffffff; (clip)++; } \`
			`else if( tmpsum < REAL_MINUS_S32 ) { *(samples) = -0x7fffffff-1; (clip)++; } \`
			`else { *(samples) = REAL_TO_S32(tmpsum); } \`
			`}`

			`/* Produce an 8bit sample, via 16bit intermediate. */`
			`#define WRITE_8BIT_SAMPLE(samples,sum,clip) \`
			`{ \`
			`short write_8bit_tmp; \`
			`if( (sum) > REAL_PLUS_32767) { write_8bit_tmp = 0x7fff; (clip)++; } \`
			`else if( (sum) < REAL_MINUS_32768) { write_8bit_tmp = -0x8000; (clip)++; } \`
			`else { write_8bit_tmp = REAL_TO_SHORT(sum); } \`
			`*(samples) = fr->conv16to8[write_8bit_tmp>>AUSHIFT]; \`
			`}`
			`#ifndef REAL_IS_FIXED`
			`#define WRITE_REAL_SAMPLE(samples,sum,clip) (samples) = ((real)1./SHORT_SCALE)(sum)`
			`#endif`

			`#endif`