| /* |
| * Copyright (c) 2013 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 |
| * |
| */ |
| |
| #if defined(MIPS32_LE) |
| |
| #include "webrtc/common_audio/signal_processing/include/signal_processing_library.h" |
| |
| // 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) |
| |
| // decimator |
| void WebRtcSpl_DownsampleBy2(const int16_t* in, |
| size_t len, |
| int16_t* out, |
| int32_t* filtState) { |
| int32_t out32; |
| size_t i, len1; |
| |
| 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]; |
| |
| #if defined(MIPS_DSP_R2_LE) |
| int32_t k1Res0, k1Res1, k1Res2, k2Res0, k2Res1, k2Res2; |
| |
| k1Res0= 3284; |
| k1Res1= 24441; |
| k1Res2= 49528; |
| k2Res0= 12199; |
| k2Res1= 37471; |
| k2Res2= 60255; |
| len1 = (len >> 1); |
| |
| const int32_t* inw = (int32_t*)in; |
| int32_t tmp11, tmp12, tmp21, tmp22; |
| int32_t in322, in321; |
| int32_t diff1, diff2; |
| for (i = len1; i > 0; i--) { |
| __asm__ volatile ( |
| "lh %[in321], 0(%[inw]) \n\t" |
| "lh %[in322], 2(%[inw]) \n\t" |
| |
| "sll %[in321], %[in321], 10 \n\t" |
| "sll %[in322], %[in322], 10 \n\t" |
| |
| "addiu %[inw], %[inw], 4 \n\t" |
| |
| "subu %[diff1], %[in321], %[state1] \n\t" |
| "subu %[diff2], %[in322], %[state5] \n\t" |
| |
| : [in322] "=&r" (in322), [in321] "=&r" (in321), |
| [diff1] "=&r" (diff1), [diff2] "=r" (diff2), [inw] "+r" (inw) |
| : [state1] "r" (state1), [state5] "r" (state5) |
| : "memory" |
| ); |
| |
| __asm__ volatile ( |
| "mult $ac0, %[diff1], %[k2Res0] \n\t" |
| "mult $ac1, %[diff2], %[k1Res0] \n\t" |
| |
| "extr.w %[tmp11], $ac0, 16 \n\t" |
| "extr.w %[tmp12], $ac1, 16 \n\t" |
| |
| "addu %[tmp11], %[state0], %[tmp11] \n\t" |
| "addu %[tmp12], %[state4], %[tmp12] \n\t" |
| |
| "addiu %[state0], %[in321], 0 \n\t" |
| "addiu %[state4], %[in322], 0 \n\t" |
| |
| "subu %[diff1], %[tmp11], %[state2] \n\t" |
| "subu %[diff2], %[tmp12], %[state6] \n\t" |
| |
| "mult $ac0, %[diff1], %[k2Res1] \n\t" |
| "mult $ac1, %[diff2], %[k1Res1] \n\t" |
| |
| "extr.w %[tmp21], $ac0, 16 \n\t" |
| "extr.w %[tmp22], $ac1, 16 \n\t" |
| |
| "addu %[tmp21], %[state1], %[tmp21] \n\t" |
| "addu %[tmp22], %[state5], %[tmp22] \n\t" |
| |
| "addiu %[state1], %[tmp11], 0 \n\t" |
| "addiu %[state5], %[tmp12], 0 \n\t" |
| : [tmp22] "=r" (tmp22), [tmp21] "=&r" (tmp21), |
| [tmp11] "=&r" (tmp11), [state0] "+r" (state0), |
| [state1] "+r" (state1), |
| [state2] "+r" (state2), |
| [state4] "+r" (state4), [tmp12] "=&r" (tmp12), |
| [state6] "+r" (state6), [state5] "+r" (state5) |
| : [k1Res1] "r" (k1Res1), [k2Res1] "r" (k2Res1), [k2Res0] "r" (k2Res0), |
| [diff2] "r" (diff2), [diff1] "r" (diff1), [in322] "r" (in322), |
| [in321] "r" (in321), [k1Res0] "r" (k1Res0) |
| : "hi", "lo", "$ac1hi", "$ac1lo" |
| ); |
| |
| // upper allpass filter |
| __asm__ volatile ( |
| "subu %[diff1], %[tmp21], %[state3] \n\t" |
| "subu %[diff2], %[tmp22], %[state7] \n\t" |
| |
| "mult $ac0, %[diff1], %[k2Res2] \n\t" |
| "mult $ac1, %[diff2], %[k1Res2] \n\t" |
| "extr.w %[state3], $ac0, 16 \n\t" |
| "extr.w %[state7], $ac1, 16 \n\t" |
| "addu %[state3], %[state2], %[state3] \n\t" |
| "addu %[state7], %[state6], %[state7] \n\t" |
| |
| "addiu %[state2], %[tmp21], 0 \n\t" |
| "addiu %[state6], %[tmp22], 0 \n\t" |
| |
| // add two allpass outputs, divide by two and round |
| "addu %[out32], %[state3], %[state7] \n\t" |
| "addiu %[out32], %[out32], 1024 \n\t" |
| "sra %[out32], %[out32], 11 \n\t" |
| : [state3] "+r" (state3), [state6] "+r" (state6), |
| [state2] "+r" (state2), [diff2] "=&r" (diff2), |
| [out32] "=r" (out32), [diff1] "=&r" (diff1), [state7] "+r" (state7) |
| : [tmp22] "r" (tmp22), [tmp21] "r" (tmp21), |
| [k1Res2] "r" (k1Res2), [k2Res2] "r" (k2Res2) |
| : "hi", "lo", "$ac1hi", "$ac1lo" |
| ); |
| |
| // limit amplitude to prevent wrap-around, and write to output array |
| *out++ = WebRtcSpl_SatW32ToW16(out32); |
| } |
| #else // #if defined(MIPS_DSP_R2_LE) |
| int32_t tmp1, tmp2, diff; |
| int32_t in32; |
| len1 = (len >> 1)/4; |
| for (i = len1; i > 0; i--) { |
| // lower allpass filter |
| in32 = (int32_t)(*in++) << 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++) << 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); |
| // lower allpass filter |
| in32 = (int32_t)(*in++) << 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++) << 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); |
| // lower allpass filter |
| in32 = (int32_t)(*in++) << 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++) << 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); |
| // lower allpass filter |
| in32 = (int32_t)(*in++) << 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++) << 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); |
| } |
| #endif // #if defined(MIPS_DSP_R2_LE) |
| __asm__ volatile ( |
| "sw %[state0], 0(%[filtState]) \n\t" |
| "sw %[state1], 4(%[filtState]) \n\t" |
| "sw %[state2], 8(%[filtState]) \n\t" |
| "sw %[state3], 12(%[filtState]) \n\t" |
| "sw %[state4], 16(%[filtState]) \n\t" |
| "sw %[state5], 20(%[filtState]) \n\t" |
| "sw %[state6], 24(%[filtState]) \n\t" |
| "sw %[state7], 28(%[filtState]) \n\t" |
| : |
| : [state0] "r" (state0), [state1] "r" (state1), [state2] "r" (state2), |
| [state3] "r" (state3), [state4] "r" (state4), [state5] "r" (state5), |
| [state6] "r" (state6), [state7] "r" (state7), [filtState] "r" (filtState) |
| : "memory" |
| ); |
| } |
| |
| #endif // #if defined(MIPS32_LE) |