common_audio/signal_processing/resample_by_2.c - src.git - Git at Google

 /*
  *  Copyright (c) 2011 The WebRTC project authors. All Rights Reserved.
  *
  *  Use of this source code is governed by a BSD-style license
  *  that can be found in the LICENSE file in the root of the source
  *  tree. An additional intellectual property rights grant can be found
  *  in the file PATENTS.  All contributing project authors may
  *  be found in the AUTHORS file in the root of the source tree.
  */


 /*
  * This file contains the resampling by two functions.
  * The description header can be found in signal_processing_library.h
  *
  */

 #include "common_audio/signal_processing/include/signal_processing_library.h"

 #ifdef WEBRTC_ARCH_ARM_V7

 // allpass filter coefficients.
 static const uint32_t kResampleAllpass1[3] = {3284, 24441, 49528 << 15};
 static const uint32_t kResampleAllpass2[3] =
   {12199, 37471 << 15, 60255 << 15};

 // Multiply two 32-bit values and accumulate to another input value.
 // Return: state + ((diff * tbl_value) >> 16)

 static __inline int32_t MUL_ACCUM_1(int32_t tbl_value,
                                     int32_t diff,
                                     int32_t state) {
   int32_t result;
   __asm __volatile ("smlawb %0, %1, %2, %3": "=r"(result): "r"(diff),
                                    "r"(tbl_value), "r"(state));
   return result;
 }

 // Multiply two 32-bit values and accumulate to another input value.
 // Return: Return: state + (((diff << 1) * tbl_value) >> 32)
 //
 // The reason to introduce this function is that, in case we can't use smlawb
 // instruction (in MUL_ACCUM_1) due to input value range, we can still use
 // smmla to save some cycles.

 static __inline int32_t MUL_ACCUM_2(int32_t tbl_value,
                                     int32_t diff,
                                     int32_t state) {
   int32_t result;
   __asm __volatile ("smmla %0, %1, %2, %3": "=r"(result): "r"(diff << 1),
                                   "r"(tbl_value), "r"(state));
   return result;
 }

 #else

 // allpass filter coefficients.
 static const uint16_t kResampleAllpass1[3] = {3284, 24441, 49528};
 static const uint16_t kResampleAllpass2[3] = {12199, 37471, 60255};

 // Multiply a 32-bit value with a 16-bit value and accumulate to another input:
 #define MUL_ACCUM_1(a, b, c) WEBRTC_SPL_SCALEDIFF32(a, b, c)
 #define MUL_ACCUM_2(a, b, c) WEBRTC_SPL_SCALEDIFF32(a, b, c)

 #endif  // WEBRTC_ARCH_ARM_V7


 // decimator
 #if !defined(MIPS32_LE)
 void WebRtcSpl_DownsampleBy2(const int16_t* in, size_t len,
                              int16_t* out, int32_t* filtState) {
   int32_t tmp1, tmp2, diff, in32, out32;
   size_t i;

   register int32_t state0 = filtState[0];
   register int32_t state1 = filtState[1];
   register int32_t state2 = filtState[2];
   register int32_t state3 = filtState[3];
   register int32_t state4 = filtState[4];
   register int32_t state5 = filtState[5];
   register int32_t state6 = filtState[6];
   register int32_t state7 = filtState[7];

   for (i = (len >> 1); i > 0; i--) {
     // lower allpass filter
     in32 = (int32_t)(*in++) * (1 << 10);
     diff = in32 - state1;
     tmp1 = MUL_ACCUM_1(kResampleAllpass2[0], diff, state0);
     state0 = in32;
     diff = tmp1 - state2;
     tmp2 = MUL_ACCUM_2(kResampleAllpass2[1], diff, state1);
     state1 = tmp1;
     diff = tmp2 - state3;
     state3 = MUL_ACCUM_2(kResampleAllpass2[2], diff, state2);
     state2 = tmp2;

     // upper allpass filter
     in32 = (int32_t)(*in++) * (1 << 10);
     diff = in32 - state5;
     tmp1 = MUL_ACCUM_1(kResampleAllpass1[0], diff, state4);
     state4 = in32;
     diff = tmp1 - state6;
     tmp2 = MUL_ACCUM_1(kResampleAllpass1[1], diff, state5);
     state5 = tmp1;
     diff = tmp2 - state7;
     state7 = MUL_ACCUM_2(kResampleAllpass1[2], diff, state6);
     state6 = tmp2;

     // add two allpass outputs, divide by two and round
     out32 = (state3 + state7 + 1024) >> 11;

     // limit amplitude to prevent wrap-around, and write to output array
     *out++ = WebRtcSpl_SatW32ToW16(out32);
   }

   filtState[0] = state0;
   filtState[1] = state1;
   filtState[2] = state2;
   filtState[3] = state3;
   filtState[4] = state4;
   filtState[5] = state5;
   filtState[6] = state6;
   filtState[7] = state7;
 }
 #endif  // #if defined(MIPS32_LE)


 void WebRtcSpl_UpsampleBy2(const int16_t* in, size_t len,
                            int16_t* out, int32_t* filtState) {
   int32_t tmp1, tmp2, diff, in32, out32;
   size_t i;

   register int32_t state0 = filtState[0];
   register int32_t state1 = filtState[1];
   register int32_t state2 = filtState[2];
   register int32_t state3 = filtState[3];
   register int32_t state4 = filtState[4];
   register int32_t state5 = filtState[5];
   register int32_t state6 = filtState[6];
   register int32_t state7 = filtState[7];

   for (i = len; i > 0; i--) {
     // lower allpass filter
     in32 = (int32_t)(*in++) * (1 << 10);
     diff = in32 - state1;
     tmp1 = MUL_ACCUM_1(kResampleAllpass1[0], diff, state0);
     state0 = in32;
     diff = tmp1 - state2;
     tmp2 = MUL_ACCUM_1(kResampleAllpass1[1], diff, state1);
     state1 = tmp1;
     diff = tmp2 - state3;
     state3 = MUL_ACCUM_2(kResampleAllpass1[2], diff, state2);
     state2 = tmp2;

     // round; limit amplitude to prevent wrap-around; write to output array
     out32 = (state3 + 512) >> 10;
     *out++ = WebRtcSpl_SatW32ToW16(out32);

     // upper allpass filter
     diff = in32 - state5;
     tmp1 = MUL_ACCUM_1(kResampleAllpass2[0], diff, state4);
     state4 = in32;
     diff = tmp1 - state6;
     tmp2 = MUL_ACCUM_2(kResampleAllpass2[1], diff, state5);
     state5 = tmp1;
     diff = tmp2 - state7;
     state7 = MUL_ACCUM_2(kResampleAllpass2[2], diff, state6);
     state6 = tmp2;

     // round; limit amplitude to prevent wrap-around; write to output array
     out32 = (state7 + 512) >> 10;
     *out++ = WebRtcSpl_SatW32ToW16(out32);
   }

   filtState[0] = state0;
   filtState[1] = state1;
   filtState[2] = state2;
   filtState[3] = state3;
   filtState[4] = state4;
   filtState[5] = state5;
   filtState[6] = state6;
   filtState[7] = state7;
 }
	/*
	* Copyright (c) 2011 The WebRTC project authors. All Rights Reserved.
	*
	* Use of this source code is governed by a BSD-style license
	* that can be found in the LICENSE file in the root of the source
	* tree. An additional intellectual property rights grant can be found
	* in the file PATENTS. All contributing project authors may
	* be found in the AUTHORS file in the root of the source tree.
	*/


	/*
	* This file contains the resampling by two functions.
	* The description header can be found in signal_processing_library.h
	*
	*/

	#include "common_audio/signal_processing/include/signal_processing_library.h"

	#ifdef WEBRTC_ARCH_ARM_V7

	// allpass filter coefficients.
	static const uint32_t kResampleAllpass1[3] = {3284, 24441, 49528 << 15};
	static const uint32_t kResampleAllpass2[3] =
	{12199, 37471 << 15, 60255 << 15};

	// Multiply two 32-bit values and accumulate to another input value.
	// Return: state + ((diff * tbl_value) >> 16)

	static __inline int32_t MUL_ACCUM_1(int32_t tbl_value,
	int32_t diff,
	int32_t state) {
	int32_t result;
	__asm __volatile ("smlawb %0, %1, %2, %3": "=r"(result): "r"(diff),
	"r"(tbl_value), "r"(state));
	return result;
	}

	// Multiply two 32-bit values and accumulate to another input value.
	// Return: Return: state + (((diff << 1) * tbl_value) >> 32)
	//
	// The reason to introduce this function is that, in case we can't use smlawb
	// instruction (in MUL_ACCUM_1) due to input value range, we can still use
	// smmla to save some cycles.

	static __inline int32_t MUL_ACCUM_2(int32_t tbl_value,
	int32_t diff,
	int32_t state) {
	int32_t result;
	__asm __volatile ("smmla %0, %1, %2, %3": "=r"(result): "r"(diff << 1),
	"r"(tbl_value), "r"(state));
	return result;
	}

	#else

	// allpass filter coefficients.
	static const uint16_t kResampleAllpass1[3] = {3284, 24441, 49528};
	static const uint16_t kResampleAllpass2[3] = {12199, 37471, 60255};

	// Multiply a 32-bit value with a 16-bit value and accumulate to another input:
	#define MUL_ACCUM_1(a, b, c) WEBRTC_SPL_SCALEDIFF32(a, b, c)
	#define MUL_ACCUM_2(a, b, c) WEBRTC_SPL_SCALEDIFF32(a, b, c)

	#endif // WEBRTC_ARCH_ARM_V7


	// decimator
	#if !defined(MIPS32_LE)
	void WebRtcSpl_DownsampleBy2(const int16_t* in, size_t len,
	int16_t* out, int32_t* filtState) {
	int32_t tmp1, tmp2, diff, in32, out32;
	size_t i;

	register int32_t state0 = filtState[0];
	register int32_t state1 = filtState[1];
	register int32_t state2 = filtState[2];
	register int32_t state3 = filtState[3];
	register int32_t state4 = filtState[4];
	register int32_t state5 = filtState[5];
	register int32_t state6 = filtState[6];
	register int32_t state7 = filtState[7];

	for (i = (len >> 1); i > 0; i--) {
	// lower allpass filter
	in32 = (int32_t)(in++) (1 << 10);
	diff = in32 - state1;
	tmp1 = MUL_ACCUM_1(kResampleAllpass2[0], diff, state0);
	state0 = in32;
	diff = tmp1 - state2;
	tmp2 = MUL_ACCUM_2(kResampleAllpass2[1], diff, state1);
	state1 = tmp1;
	diff = tmp2 - state3;
	state3 = MUL_ACCUM_2(kResampleAllpass2[2], diff, state2);
	state2 = tmp2;

	// upper allpass filter
	in32 = (int32_t)(in++) (1 << 10);
	diff = in32 - state5;
	tmp1 = MUL_ACCUM_1(kResampleAllpass1[0], diff, state4);
	state4 = in32;
	diff = tmp1 - state6;
	tmp2 = MUL_ACCUM_1(kResampleAllpass1[1], diff, state5);
	state5 = tmp1;
	diff = tmp2 - state7;
	state7 = MUL_ACCUM_2(kResampleAllpass1[2], diff, state6);
	state6 = tmp2;

	// add two allpass outputs, divide by two and round
	out32 = (state3 + state7 + 1024) >> 11;

	// limit amplitude to prevent wrap-around, and write to output array
	*out++ = WebRtcSpl_SatW32ToW16(out32);
	}

	filtState[0] = state0;
	filtState[1] = state1;
	filtState[2] = state2;
	filtState[3] = state3;
	filtState[4] = state4;
	filtState[5] = state5;
	filtState[6] = state6;
	filtState[7] = state7;
	}
	#endif // #if defined(MIPS32_LE)


	void WebRtcSpl_UpsampleBy2(const int16_t* in, size_t len,
	int16_t* out, int32_t* filtState) {
	int32_t tmp1, tmp2, diff, in32, out32;
	size_t i;

	register int32_t state0 = filtState[0];
	register int32_t state1 = filtState[1];
	register int32_t state2 = filtState[2];
	register int32_t state3 = filtState[3];
	register int32_t state4 = filtState[4];
	register int32_t state5 = filtState[5];
	register int32_t state6 = filtState[6];
	register int32_t state7 = filtState[7];

	for (i = len; i > 0; i--) {
	// lower allpass filter
	in32 = (int32_t)(in++) (1 << 10);
	diff = in32 - state1;
	tmp1 = MUL_ACCUM_1(kResampleAllpass1[0], diff, state0);
	state0 = in32;
	diff = tmp1 - state2;
	tmp2 = MUL_ACCUM_1(kResampleAllpass1[1], diff, state1);
	state1 = tmp1;
	diff = tmp2 - state3;
	state3 = MUL_ACCUM_2(kResampleAllpass1[2], diff, state2);
	state2 = tmp2;

	// round; limit amplitude to prevent wrap-around; write to output array
	out32 = (state3 + 512) >> 10;
	*out++ = WebRtcSpl_SatW32ToW16(out32);

	// upper allpass filter
	diff = in32 - state5;
	tmp1 = MUL_ACCUM_1(kResampleAllpass2[0], diff, state4);
	state4 = in32;
	diff = tmp1 - state6;
	tmp2 = MUL_ACCUM_2(kResampleAllpass2[1], diff, state5);
	state5 = tmp1;
	diff = tmp2 - state7;
	state7 = MUL_ACCUM_2(kResampleAllpass2[2], diff, state6);
	state6 = tmp2;

	// round; limit amplitude to prevent wrap-around; write to output array
	out32 = (state7 + 512) >> 10;
	*out++ = WebRtcSpl_SatW32ToW16(out32);
	}

	filtState[0] = state0;
	filtState[1] = state1;
	filtState[2] = state2;
	filtState[3] = state3;
	filtState[4] = state4;
	filtState[5] = state5;
	filtState[6] = state6;
	filtState[7] = state7;
	}