e3faadaafe
For a slightly thorough explaination, please refer to [1] http://people.freebsd.org/~ariff/SOUND_4.TXT.html . Summary of changes includes: 1 Volume Per-Channel (vpc). Provides private / standalone volume control unique per-stream pcm channel without touching master volume / pcm. Applications can directly use SNDCTL_DSP_[GET|SET][PLAY|REC]VOL, or for backwards compatibility, SOUND_MIXER_PCM through the opened dsp device instead of /dev/mixer. Special "bypass" mode is enabled through /dev/mixer which will automatically detect if the adjustment is made through /dev/mixer and forward its request to this private volume controller. Changes to this volume object will not interfere with other channels. Requirements: - SNDCTL_DSP_[GET|SET][PLAY|REC]_VOL are newer ioctls (OSSv4) which require specific application modifications (preferred). - No modifications required for using bypass mode, so applications like mplayer or xmms should work out of the box. Kernel hints: - hint.pcm.%d.vpc (0 = disable vpc). Kernel sysctls: - hw.snd.vpc_mixer_bypass (default: 1). Enable or disable /dev/mixer bypass mode. - hw.snd.vpc_autoreset (default: 1). By default, closing/opening /dev/dsp will reset the volume back to 0 db gain/attenuation. Setting this to 0 will preserve its settings across device closing/opening. - hw.snd.vpc_reset (default: 0). Panic/reset button to reset all volume settings back to 0 db. - hw.snd.vpc_0db (default: 45). 0 db relative to linear mixer value. 2 High quality fixed-point Bandlimited SINC sampling rate converter, based on Julius O'Smith's Digital Audio Resampling - http://ccrma.stanford.edu/~jos/resample/. It includes a filter design script written in awk (the clumsiest joke I've ever written) - 100% 32bit fixed-point, 64bit accumulator. - Possibly among the fastest (if not fastest) of its kind. - Resampling quality is tunable, either runtime or during kernel compilation (FEEDER_RATE_PRESETS). - Quality can be further customized during kernel compilation by defining FEEDER_RATE_PRESETS in /etc/make.conf. Kernel sysctls: - hw.snd.feeder_rate_quality. 0 - Zero-order Hold (ZOH). Fastest, bad quality. 1 - Linear Interpolation (LINEAR). Slightly slower than ZOH, better quality but still does not eliminate aliasing. 2 - (and above) - Sinc Interpolation(SINC). Best quality. SINC quality always start from 2 and above. Rough quality comparisons: - http://people.freebsd.org/~ariff/z_comparison/ 3 Bit-perfect mode. Bypasses all feeder/dsp effects. Pure sound will be directly fed into the hardware. 4 Parametric (compile time) Software Equalizer (Bass/Treble mixer). Can be customized by defining FEEDER_EQ_PRESETS in /etc/make.conf. 5 Transparent/Adaptive Virtual Channel. Now you don't have to disable vchans in order to make digital format pass through. It also makes vchans more dynamic by choosing a better format/rate among all the concurrent streams, which means that dev.pcm.X.play.vchanformat/rate becomes sort of optional. 6 Exclusive Stream, with special open() mode O_EXCL. This will "mute" other concurrent vchan streams and only allow a single channel with O_EXCL set to keep producing sound. Other Changes: * most feeder_* stuffs are compilable in userland. Let's not speculate whether we should go all out for it (save that for FreeBSD 16.0-RELEASE). * kobj signature fixups, thanks to Andriy Gapon <avg@freebsd.org> * pull out channel mixing logic out of vchan.c and create its own feeder_mixer for world justice. * various refactoring here and there, for good or bad. * activation of few more OSSv4 ioctls() (see [1] above). * opt_snd.h for possible compile time configuration: (mostly for debugging purposes, don't try these at home) SND_DEBUG SND_DIAGNOSTIC SND_FEEDER_MULTIFORMAT SND_FEEDER_FULL_MULTIFORMAT SND_FEEDER_RATE_HP SND_PCM_64 SND_OLDSTEREO Manual page updates are on the way. Tested by: joel, Olivier SMEDTS <olivier at gid0 d org>, too many unsung / unnamed heroes.
439 lines
15 KiB
C
439 lines
15 KiB
C
/*-
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* Copyright (c) 2006-2009 Ariff Abdullah <ariff@FreeBSD.org>
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* All rights reserved.
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*
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* Redistribution and use in source and binary forms, with or without
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* modification, are permitted provided that the following conditions
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* are met:
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* 1. Redistributions of source code must retain the above copyright
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* notice, this list of conditions and the following disclaimer.
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* 2. Redistributions in binary form must reproduce the above copyright
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* notice, this list of conditions and the following disclaimer in the
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* documentation and/or other materials provided with the distribution.
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*
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* THIS SOFTWARE IS PROVIDED BY THE AUTHOR AND CONTRIBUTORS ``AS IS'' AND
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* ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
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* IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
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* ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE LIABLE
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* FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
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* DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
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* OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
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* HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
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* LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
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* OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
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* SUCH DAMAGE.
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*
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* $FreeBSD$
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*/
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#ifndef _SND_PCM_H_
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#define _SND_PCM_H_
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#include <sys/param.h>
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/*
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* Macros for reading/writing PCM sample / int values from bytes array.
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* Since every process is done using signed integer (and to make our life
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* less miserable), unsigned sample will be converted to its signed
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* counterpart and restored during writing back. To avoid overflow,
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* we truncate 32bit (and only 32bit) samples down to 24bit (see below
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* for the reason), unless SND_PCM_64 is defined.
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*/
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/*
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* Automatically turn on 64bit arithmetic on suitable archs
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* (amd64 64bit, ia64, etc..) for wider 32bit samples / integer processing.
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*/
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#if LONG_BIT >= 64
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#undef SND_PCM_64
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#define SND_PCM_64 1
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#endif
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typedef int32_t intpcm_t;
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typedef int32_t intpcm8_t;
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typedef int32_t intpcm16_t;
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typedef int32_t intpcm24_t;
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typedef uint32_t uintpcm_t;
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typedef uint32_t uintpcm8_t;
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typedef uint32_t uintpcm16_t;
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typedef uint32_t uintpcm24_t;
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#ifdef SND_PCM_64
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typedef int64_t intpcm32_t;
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typedef uint64_t uintpcm32_t;
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#else
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typedef int32_t intpcm32_t;
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typedef uint32_t uintpcm32_t;
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#endif
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typedef int64_t intpcm64_t;
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typedef uint64_t uintpcm64_t;
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/* 32bit fixed point shift */
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#define PCM_FXSHIFT 8
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#define PCM_S8_MAX 0x7f
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#define PCM_S8_MIN -0x80
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#define PCM_S16_MAX 0x7fff
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#define PCM_S16_MIN -0x8000
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#define PCM_S24_MAX 0x7fffff
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#define PCM_S24_MIN -0x800000
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#ifdef SND_PCM_64
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#if LONG_BIT >= 64
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#define PCM_S32_MAX 0x7fffffffL
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#define PCM_S32_MIN -0x80000000L
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#else
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#define PCM_S32_MAX 0x7fffffffLL
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#define PCM_S32_MIN -0x80000000LL
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#endif
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#else
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#define PCM_S32_MAX 0x7fffffff
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#define PCM_S32_MIN (-0x7fffffff - 1)
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#endif
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/* Bytes-per-sample definition */
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#define PCM_8_BPS 1
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#define PCM_16_BPS 2
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#define PCM_24_BPS 3
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#define PCM_32_BPS 4
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#define INTPCM_T(v) ((intpcm_t)(v))
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#define INTPCM8_T(v) ((intpcm8_t)(v))
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#define INTPCM16_T(v) ((intpcm16_t)(v))
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#define INTPCM24_T(v) ((intpcm24_t)(v))
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#define INTPCM32_T(v) ((intpcm32_t)(v))
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#if BYTE_ORDER == LITTLE_ENDIAN
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#define _PCM_READ_S16_LE(b8) INTPCM_T(*((int16_t *)(b8)))
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#define _PCM_READ_S32_LE(b8) INTPCM_T(*((int32_t *)(b8)))
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#define _PCM_READ_S16_BE(b8) \
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INTPCM_T((b8)[1] | (((int8_t)((b8)[0])) << 8))
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#define _PCM_READ_S32_BE(b8) \
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INTPCM_T((b8)[3] | ((b8)[2] << 8) | ((b8)[1] << 16) | \
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(((int8_t)((b8)[0])) << 24))
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#define _PCM_WRITE_S16_LE(b8, val) do { \
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*((int16_t *)(b8)) = (val); \
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} while (0)
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#define _PCM_WRITE_S32_LE(b8, val) do { \
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*((int32_t *)(b8)) = (val); \
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} while (0)
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#define _PCM_WRITE_S16_BE(bb8, vval) do { \
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intpcm_t val = (vval); \
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uint8_t *b8 = (bb8); \
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b8[1] = val; \
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b8[0] = val >> 8; \
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} while (0)
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#define _PCM_WRITE_S32_BE(bb8, vval) do { \
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intpcm_t val = (vval); \
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uint8_t *b8 = (bb8); \
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b8[3] = val; \
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b8[2] = val >> 8; \
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b8[1] = val >> 16; \
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b8[0] = val >> 24; \
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} while (0)
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#define _PCM_READ_U16_LE(b8) \
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INTPCM_T((int16_t)(*((uint16_t *)(b8)) ^ 0x8000))
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#define _PCM_READ_U32_LE(b8) \
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INTPCM_T((int32_t)(*((uint32_t *)(b8)) ^ 0x80000000))
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#define _PCM_READ_U16_BE(b8) \
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INTPCM_T((b8)[1] | (((int8_t)((b8)[0] ^ 0x80)) << 8))
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#define _PCM_READ_U32_BE(b8) \
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INTPCM_T((b8)[3] | ((b8)[2] << 8) | ((b8)[1] << 16) | \
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(((int8_t)((b8)[0] ^ 0x80)) << 24))
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#define _PCM_WRITE_U16_LE(b8, val) do { \
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*((uint16_t *)(b8)) = (val) ^ 0x8000; \
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} while (0)
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#define _PCM_WRITE_U32_LE(b8, val) do { \
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*((uint32_t *)(b8)) = (val) ^ 0x80000000; \
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} while (0)
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#define _PCM_WRITE_U16_BE(bb8, vval) do { \
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intpcm_t val = (vval); \
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uint8_t *b8 = (bb8); \
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b8[1] = val; \
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b8[0] = (val >> 8) ^ 0x80; \
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} while (0)
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#define _PCM_WRITE_U32_BE(bb8, vval) do { \
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intpcm_t val = (vval); \
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uint8_t *b8 = (bb8); \
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b8[3] = val; \
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b8[2] = val >> 8; \
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b8[1] = val >> 16; \
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b8[0] = (val >> 24) ^ 0x80; \
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} while (0)
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#define _PCM_READ_S16_NE(b8) _PCM_READ_S16_LE(b8)
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#define _PCM_READ_U16_NE(b8) _PCM_READ_U16_LE(b8)
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#define _PCM_READ_S32_NE(b8) _PCM_READ_S32_LE(b8)
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#define _PCM_READ_U32_NE(b8) _PCM_READ_U32_LE(b8)
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#define _PCM_WRITE_S16_NE(b6) _PCM_WRITE_S16_LE(b8)
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#define _PCM_WRITE_U16_NE(b6) _PCM_WRITE_U16_LE(b8)
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#define _PCM_WRITE_S32_NE(b6) _PCM_WRITE_S32_LE(b8)
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#define _PCM_WRITE_U32_NE(b6) _PCM_WRITE_U32_LE(b8)
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#else /* !LITTLE_ENDIAN */
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#define _PCM_READ_S16_LE(b8) \
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INTPCM_T((b8)[0] | (((int8_t)((b8)[1])) << 8))
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#define _PCM_READ_S32_LE(b8) \
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INTPCM_T((b8)[0] | ((b8)[1] << 8) | ((b8)[2] << 16) | \
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(((int8_t)((b8)[3])) << 24))
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#define _PCM_READ_S16_BE(b8) INTPCM_T(*((int16_t *)(b8)))
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#define _PCM_READ_S32_BE(b8) INTPCM_T(*((int32_t *)(b8)))
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#define _PCM_WRITE_S16_LE(bb8, vval) do { \
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intpcm_t val = (vval); \
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uint8_t *b8 = (bb8); \
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b8[0] = val; \
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b8[1] = val >> 8; \
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} while (0)
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#define _PCM_WRITE_S32_LE(bb8, vval) do { \
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intpcm_t val = (vval); \
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uint8_t *b8 = (bb8); \
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b8[0] = val; \
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b8[1] = val >> 8; \
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b8[2] = val >> 16; \
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b8[3] = val >> 24; \
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} while (0)
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#define _PCM_WRITE_S16_BE(b8, val) do { \
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*((int16_t *)(b8)) = (val); \
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} while (0)
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#define _PCM_WRITE_S32_BE(b8, val) do { \
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*((int32_t *)(b8)) = (val); \
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} while (0)
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#define _PCM_READ_U16_LE(b8) \
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INTPCM_T((b8)[0] | (((int8_t)((b8)[1] ^ 0x80)) << 8))
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#define _PCM_READ_U32_LE(b8) \
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INTPCM_T((b8)[0] | ((b8)[1] << 8) | ((b8)[2] << 16) | \
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(((int8_t)((b8)[3] ^ 0x80)) << 24))
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#define _PCM_READ_U16_BE(b8) \
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INTPCM_T((int16_t)(*((uint16_t *)(b8)) ^ 0x8000))
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#define _PCM_READ_U32_BE(b8) \
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INTPCM_T((int32_t)(*((uint32_t *)(b8)) ^ 0x80000000))
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#define _PCM_WRITE_U16_LE(bb8, vval) do { \
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intpcm_t val = (vval); \
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uint8_t *b8 = (bb8); \
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b8[0] = val; \
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b8[1] = (val >> 8) ^ 0x80; \
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} while (0)
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#define _PCM_WRITE_U32_LE(bb8, vval) do { \
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intpcm_t val = (vval); \
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uint8_t *b8 = (bb8); \
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b8[0] = val; \
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b8[1] = val >> 8; \
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b8[2] = val >> 16; \
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b8[3] = (val >> 24) ^ 0x80; \
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} while (0)
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#define _PCM_WRITE_U16_BE(b8, val) do { \
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*((uint16_t *)(b8)) = (val) ^ 0x8000; \
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} while (0)
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#define _PCM_WRITE_U32_BE(b8, val) do { \
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*((uint32_t *)(b8)) = (val) ^ 0x80000000; \
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} while (0)
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#define _PCM_READ_S16_NE(b8) _PCM_READ_S16_BE(b8)
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#define _PCM_READ_U16_NE(b8) _PCM_READ_U16_BE(b8)
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#define _PCM_READ_S32_NE(b8) _PCM_READ_S32_BE(b8)
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#define _PCM_READ_U32_NE(b8) _PCM_READ_U32_BE(b8)
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#define _PCM_WRITE_S16_NE(b6) _PCM_WRITE_S16_BE(b8)
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#define _PCM_WRITE_U16_NE(b6) _PCM_WRITE_U16_BE(b8)
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#define _PCM_WRITE_S32_NE(b6) _PCM_WRITE_S32_BE(b8)
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#define _PCM_WRITE_U32_NE(b6) _PCM_WRITE_U32_BE(b8)
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#endif /* LITTLE_ENDIAN */
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#define _PCM_READ_S24_LE(b8) \
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INTPCM_T((b8)[0] | ((b8)[1] << 8) | (((int8_t)((b8)[2])) << 16))
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#define _PCM_READ_S24_BE(b8) \
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INTPCM_T((b8)[2] | ((b8)[1] << 8) | (((int8_t)((b8)[0])) << 16))
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#define _PCM_WRITE_S24_LE(bb8, vval) do { \
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intpcm_t val = (vval); \
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uint8_t *b8 = (bb8); \
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b8[0] = val; \
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b8[1] = val >> 8; \
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b8[2] = val >> 16; \
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} while (0)
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#define _PCM_WRITE_S24_BE(bb8, vval) do { \
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intpcm_t val = (vval); \
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uint8_t *b8 = (bb8); \
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b8[2] = val; \
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b8[1] = val >> 8; \
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b8[0] = val >> 16; \
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} while (0)
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#define _PCM_READ_U24_LE(b8) \
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INTPCM_T((b8)[0] | ((b8)[1] << 8) | \
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(((int8_t)((b8)[2] ^ 0x80)) << 16))
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#define _PCM_READ_U24_BE(b8) \
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INTPCM_T((b8)[2] | ((b8)[1] << 8) | \
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(((int8_t)((b8)[0] ^ 0x80)) << 16))
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#define _PCM_WRITE_U24_LE(bb8, vval) do { \
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intpcm_t val = (vval); \
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uint8_t *b8 = (bb8); \
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b8[0] = val; \
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b8[1] = val >> 8; \
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b8[2] = (val >> 16) ^ 0x80; \
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} while (0)
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#define _PCM_WRITE_U24_BE(bb8, vval) do { \
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intpcm_t val = (vval); \
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uint8_t *b8 = (bb8); \
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b8[2] = val; \
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b8[1] = val >> 8; \
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b8[0] = (val >> 16) ^ 0x80; \
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} while (0)
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#if BYTE_ORDER == LITTLE_ENDIAN
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#define _PCM_READ_S24_NE(b8) _PCM_READ_S24_LE(b8)
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#define _PCM_READ_U24_NE(b8) _PCM_READ_U24_LE(b8)
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#define _PCM_WRITE_S24_NE(b6) _PCM_WRITE_S24_LE(b8)
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#define _PCM_WRITE_U24_NE(b6) _PCM_WRITE_U24_LE(b8)
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#else /* !LITTLE_ENDIAN */
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#define _PCM_READ_S24_NE(b8) _PCM_READ_S24_BE(b8)
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#define _PCM_READ_U24_NE(b8) _PCM_READ_U24_BE(b8)
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#define _PCM_WRITE_S24_NE(b6) _PCM_WRITE_S24_BE(b8)
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#define _PCM_WRITE_U24_NE(b6) _PCM_WRITE_U24_BE(b8)
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#endif /* LITTLE_ENDIAN */
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/*
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* 8bit sample is pretty much useless since it doesn't provide
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* sufficient dynamic range throughout our filtering process.
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* For the sake of completeness, declare it anyway.
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*/
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#define _PCM_READ_S8_NE(b8) INTPCM_T(*((int8_t *)(b8)))
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#define _PCM_READ_U8_NE(b8) \
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INTPCM_T((int8_t)(*((uint8_t *)(b8)) ^ 0x80))
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#define _PCM_WRITE_S8_NE(b8, val) do { \
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*((int8_t *)(b8)) = (val); \
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} while (0)
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#define _PCM_WRITE_U8_NE(b8, val) do { \
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*((uint8_t *)(b8)) = (val) ^ 0x80; \
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} while (0)
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/*
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* Common macross. Use this instead of "_", unless we want
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* the real sample value.
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*/
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/* 8bit */
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#define PCM_READ_S8_NE(b8) _PCM_READ_S8_NE(b8)
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#define PCM_READ_U8_NE(b8) _PCM_READ_U8_NE(b8)
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#define PCM_WRITE_S8_NE(b8, val) _PCM_WRITE_S8_NE(b8, val)
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#define PCM_WRITE_U8_NE(b8, val) _PCM_WRITE_U8_NE(b8, val)
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/* 16bit */
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#define PCM_READ_S16_LE(b8) _PCM_READ_S16_LE(b8)
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#define PCM_READ_S16_BE(b8) _PCM_READ_S16_BE(b8)
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#define PCM_READ_U16_LE(b8) _PCM_READ_U16_LE(b8)
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#define PCM_READ_U16_BE(b8) _PCM_READ_U16_BE(b8)
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#define PCM_WRITE_S16_LE(b8, val) _PCM_WRITE_S16_LE(b8, val)
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#define PCM_WRITE_S16_BE(b8, val) _PCM_WRITE_S16_BE(b8, val)
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#define PCM_WRITE_U16_LE(b8, val) _PCM_WRITE_U16_LE(b8, val)
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#define PCM_WRITE_U16_BE(b8, val) _PCM_WRITE_U16_BE(b8, val)
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#define PCM_READ_S16_NE(b8) _PCM_READ_S16_NE(b8)
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#define PCM_READ_U16_NE(b8) _PCM_READ_U16_NE(b8)
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#define PCM_WRITE_S16_NE(b8) _PCM_WRITE_S16_NE(b8)
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#define PCM_WRITE_U16_NE(b8) _PCM_WRITE_U16_NE(b8)
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/* 24bit */
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#define PCM_READ_S24_LE(b8) _PCM_READ_S24_LE(b8)
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#define PCM_READ_S24_BE(b8) _PCM_READ_S24_BE(b8)
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#define PCM_READ_U24_LE(b8) _PCM_READ_U24_LE(b8)
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#define PCM_READ_U24_BE(b8) _PCM_READ_U24_BE(b8)
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#define PCM_WRITE_S24_LE(b8, val) _PCM_WRITE_S24_LE(b8, val)
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#define PCM_WRITE_S24_BE(b8, val) _PCM_WRITE_S24_BE(b8, val)
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#define PCM_WRITE_U24_LE(b8, val) _PCM_WRITE_U24_LE(b8, val)
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#define PCM_WRITE_U24_BE(b8, val) _PCM_WRITE_U24_BE(b8, val)
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#define PCM_READ_S24_NE(b8) _PCM_READ_S24_NE(b8)
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#define PCM_READ_U24_NE(b8) _PCM_READ_U24_NE(b8)
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#define PCM_WRITE_S24_NE(b8) _PCM_WRITE_S24_NE(b8)
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#define PCM_WRITE_U24_NE(b8) _PCM_WRITE_U24_NE(b8)
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/* 32bit */
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#ifdef SND_PCM_64
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#define PCM_READ_S32_LE(b8) _PCM_READ_S32_LE(b8)
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#define PCM_READ_S32_BE(b8) _PCM_READ_S32_BE(b8)
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#define PCM_READ_U32_LE(b8) _PCM_READ_U32_LE(b8)
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#define PCM_READ_U32_BE(b8) _PCM_READ_U32_BE(b8)
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#define PCM_WRITE_S32_LE(b8, val) _PCM_WRITE_S32_LE(b8, val)
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#define PCM_WRITE_S32_BE(b8, val) _PCM_WRITE_S32_BE(b8, val)
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#define PCM_WRITE_U32_LE(b8, val) _PCM_WRITE_U32_LE(b8, val)
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#define PCM_WRITE_U32_BE(b8, val) _PCM_WRITE_U32_BE(b8, val)
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#define PCM_READ_S32_NE(b8) _PCM_READ_S32_NE(b8)
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#define PCM_READ_U32_NE(b8) _PCM_READ_U32_NE(b8)
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#define PCM_WRITE_S32_NE(b8) _PCM_WRITE_S32_NE(b8)
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#define PCM_WRITE_U32_NE(b8) _PCM_WRITE_U32_NE(b8)
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#else /* !SND_PCM_64 */
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/*
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* 24bit integer ?!? This is quite unfortunate, eh? Get the fact straight:
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* Dynamic range for:
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* 1) Human =~ 140db
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* 2) 16bit = 96db (close enough)
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* 3) 24bit = 144db (perfect)
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* 4) 32bit = 196db (way too much)
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* 5) Bugs Bunny = Gazillion!@%$Erbzzztt-EINVAL db
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* Since we're not Bugs Bunny ..uh..err.. avoiding 64bit arithmetic, 24bit
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* is pretty much sufficient for our signed integer processing.
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*/
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#define PCM_READ_S32_LE(b8) (_PCM_READ_S32_LE(b8) >> PCM_FXSHIFT)
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#define PCM_READ_S32_BE(b8) (_PCM_READ_S32_BE(b8) >> PCM_FXSHIFT)
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#define PCM_READ_U32_LE(b8) (_PCM_READ_U32_LE(b8) >> PCM_FXSHIFT)
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#define PCM_READ_U32_BE(b8) (_PCM_READ_U32_BE(b8) >> PCM_FXSHIFT)
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#define PCM_READ_S32_NE(b8) (_PCM_READ_S32_NE(b8) >> PCM_FXSHIFT)
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#define PCM_READ_U32_NE(b8) (_PCM_READ_U32_NE(b8) >> PCM_FXSHIFT)
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#define PCM_WRITE_S32_LE(b8, val) \
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_PCM_WRITE_S32_LE(b8, (val) << PCM_FXSHIFT)
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#define PCM_WRITE_S32_BE(b8, val) \
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_PCM_WRITE_S32_BE(b8, (val) << PCM_FXSHIFT)
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#define PCM_WRITE_U32_LE(b8, val) \
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_PCM_WRITE_U32_LE(b8, (val) << PCM_FXSHIFT)
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#define PCM_WRITE_U32_BE(b8, val) \
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_PCM_WRITE_U32_BE(b8, (val) << PCM_FXSHIFT)
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#define PCM_WRITE_S32_NE(b8, val) \
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_PCM_WRITE_S32_NE(b8, (val) << PCM_FXSHIFT)
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#define PCM_WRITE_U32_NE(b8, val) \
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_PCM_WRITE_U32_NE(b8, (val) << PCM_FXSHIFT)
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#endif /* SND_PCM_64 */
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#define PCM_CLAMP_S8(val) \
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(((val) > PCM_S8_MAX) ? PCM_S8_MAX : \
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(((val) < PCM_S8_MIN) ? PCM_S8_MIN : (val)))
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#define PCM_CLAMP_S16(val) \
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(((val) > PCM_S16_MAX) ? PCM_S16_MAX : \
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(((val) < PCM_S16_MIN) ? PCM_S16_MIN : (val)))
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#define PCM_CLAMP_S24(val) \
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(((val) > PCM_S24_MAX) ? PCM_S24_MAX : \
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(((val) < PCM_S24_MIN) ? PCM_S24_MIN : (val)))
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#ifdef SND_PCM_64
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#define PCM_CLAMP_S32(val) \
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(((val) > PCM_S32_MAX) ? PCM_S32_MAX : \
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(((val) < PCM_S32_MIN) ? PCM_S32_MIN : (val)))
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#else /* !SND_PCM_64 */
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#define PCM_CLAMP_S32(val) \
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(((val) > PCM_S24_MAX) ? PCM_S32_MAX : \
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(((val) < PCM_S24_MIN) ? PCM_S32_MIN : \
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((val) << PCM_FXSHIFT)))
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#endif /* SND_PCM_64 */
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#define PCM_CLAMP_U8(val) PCM_CLAMP_S8(val)
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#define PCM_CLAMP_U16(val) PCM_CLAMP_S16(val)
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#define PCM_CLAMP_U24(val) PCM_CLAMP_S24(val)
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#define PCM_CLAMP_U32(val) PCM_CLAMP_S32(val)
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#endif /* !_SND_PCM_H_ */
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