/****************************************************************************** * * Copyright (C) 2014 The Android Open Source Project * Copyright 2003 - 2004 Open Interface North America, Inc. All rights * reserved. * * Licensed under the Apache License, Version 2.0 (the "License"); * you may not use this file except in compliance with the License. * You may obtain a copy of the License at: * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. * ******************************************************************************/ /******************************************************************************* $Revision: #1 $ ******************************************************************************/ /** @file @ingroup codec_internal */ /**@addgroup codec_internal*/ /**@{*/ /* * Performs an 8-point Type-II scaled DCT using the Arai-Agui-Nakajima * factorization. The scaling factors are folded into the windowing * constants. 29 adds and 5 16x32 multiplies per 8 samples. */ #include "oi_codec_sbc_private.h" #define AAN_C4_FIX (759250125) /* S1.30 759250125 0.707107*/ #define AAN_C6_FIX (410903207) /* S1.30 410903207 0.382683*/ #define AAN_Q0_FIX (581104888) /* S1.30 581104888 0.541196*/ #define AAN_Q1_FIX (1402911301) /* S1.30 1402911301 1.306563*/ /** Scales x by y bits to the right, adding a rounding factor. */ #ifndef SCALE #define SCALE(x, y) (((x) + (1 << ((y)-1))) >> (y)) #endif /** * Default C language implementation of a 32x32->32 multiply. This function may * be replaced by a platform-specific version for speed. * * @param u A signed 32-bit multiplicand * @param v A signed 32-bit multiplier * @return A signed 32-bit value corresponding to the 32 most significant bits * of the 64-bit product of u and v. */ INLINE int32_t default_mul_32s_32s_hi(int32_t u, int32_t v) { uint32_t u0, v0; int32_t u1, v1, w1, w2, t; u0 = u & 0xFFFF; u1 = u >> 16; v0 = v & 0xFFFF; v1 = v >> 16; t = u0 * v0; t = u1 * v0 + ((uint32_t)t >> 16); w1 = t & 0xFFFF; w2 = t >> 16; w1 = u0 * v1 + w1; return u1 * v1 + w2 + (w1 >> 16); } #define MUL_32S_32S_HI(_x, _y) default_mul_32s_32s_hi(_x, _y) #ifdef DEBUG_DCT PRIVATE void float_dct2_8(float* RESTRICT out, int32_t const* RESTRICT in) { #define FIX(x, bits) \ (((int)floor(0.5f + ((x) * ((float)(1 << bits))))) / ((float)(1 << bits))) #define FLOAT_BUTTERFLY(x, y) \ x += y; \ y = x - (y * 2); \ OI_ASSERT(VALID_INT32(x)); \ OI_ASSERT(VALID_INT32(y)); #define FLOAT_MULT_DCT(K, sample) (FIX(K, 20) * sample) #define FLOAT_SCALE(x, y) (((x) / (double)(1 << (y)))) double L00, L01, L02, L03, L04, L05, L06, L07; double L25; double in0, in1, in2, in3; double in4, in5, in6, in7; in0 = FLOAT_SCALE(in[0], DCTII_8_SHIFT_IN); OI_ASSERT(VALID_INT32(in0)); in1 = FLOAT_SCALE(in[1], DCTII_8_SHIFT_IN); OI_ASSERT(VALID_INT32(in1)); in2 = FLOAT_SCALE(in[2], DCTII_8_SHIFT_IN); OI_ASSERT(VALID_INT32(in2)); in3 = FLOAT_SCALE(in[3], DCTII_8_SHIFT_IN); OI_ASSERT(VALID_INT32(in3)); in4 = FLOAT_SCALE(in[4], DCTII_8_SHIFT_IN); OI_ASSERT(VALID_INT32(in4)); in5 = FLOAT_SCALE(in[5], DCTII_8_SHIFT_IN); OI_ASSERT(VALID_INT32(in5)); in6 = FLOAT_SCALE(in[6], DCTII_8_SHIFT_IN); OI_ASSERT(VALID_INT32(in6)); in7 = FLOAT_SCALE(in[7], DCTII_8_SHIFT_IN); OI_ASSERT(VALID_INT32(in7)); L00 = (in0 + in7); OI_ASSERT(VALID_INT32(L00)); L01 = (in1 + in6); OI_ASSERT(VALID_INT32(L01)); L02 = (in2 + in5); OI_ASSERT(VALID_INT32(L02)); L03 = (in3 + in4); OI_ASSERT(VALID_INT32(L03)); L04 = (in3 - in4); OI_ASSERT(VALID_INT32(L04)); L05 = (in2 - in5); OI_ASSERT(VALID_INT32(L05)); L06 = (in1 - in6); OI_ASSERT(VALID_INT32(L06)); L07 = (in0 - in7); OI_ASSERT(VALID_INT32(L07)); FLOAT_BUTTERFLY(L00, L03); FLOAT_BUTTERFLY(L01, L02); L02 += L03; OI_ASSERT(VALID_INT32(L02)); L02 = FLOAT_MULT_DCT(AAN_C4_FLOAT, L02); OI_ASSERT(VALID_INT32(L02)); FLOAT_BUTTERFLY(L00, L01); out[0] = (float)FLOAT_SCALE(L00, DCTII_8_SHIFT_0); OI_ASSERT(VALID_INT16(out[0])); out[4] = (float)FLOAT_SCALE(L01, DCTII_8_SHIFT_4); OI_ASSERT(VALID_INT16(out[4])); FLOAT_BUTTERFLY(L03, L02); out[6] = (float)FLOAT_SCALE(L02, DCTII_8_SHIFT_6); OI_ASSERT(VALID_INT16(out[6])); out[2] = (float)FLOAT_SCALE(L03, DCTII_8_SHIFT_2); OI_ASSERT(VALID_INT16(out[2])); L04 += L05; OI_ASSERT(VALID_INT32(L04)); L05 += L06; OI_ASSERT(VALID_INT32(L05)); L06 += L07; OI_ASSERT(VALID_INT32(L06)); L04 /= 2; L05 /= 2; L06 /= 2; L07 /= 2; L05 = FLOAT_MULT_DCT(AAN_C4_FLOAT, L05); OI_ASSERT(VALID_INT32(L05)); L25 = L06 - L04; OI_ASSERT(VALID_INT32(L25)); L25 = FLOAT_MULT_DCT(AAN_C6_FLOAT, L25); OI_ASSERT(VALID_INT32(L25)); L04 = FLOAT_MULT_DCT(AAN_Q0_FLOAT, L04); OI_ASSERT(VALID_INT32(L04)); L04 -= L25; OI_ASSERT(VALID_INT32(L04)); L06 = FLOAT_MULT_DCT(AAN_Q1_FLOAT, L06); OI_ASSERT(VALID_INT32(L06)); L06 -= L25; OI_ASSERT(VALID_INT32(L25)); FLOAT_BUTTERFLY(L07, L05); FLOAT_BUTTERFLY(L05, L04); out[3] = (float)(FLOAT_SCALE(L04, DCTII_8_SHIFT_3 - 1)); OI_ASSERT(VALID_INT16(out[3])); out[5] = (float)(FLOAT_SCALE(L05, DCTII_8_SHIFT_5 - 1)); OI_ASSERT(VALID_INT16(out[5])); FLOAT_BUTTERFLY(L07, L06); out[7] = (float)(FLOAT_SCALE(L06, DCTII_8_SHIFT_7 - 1)); OI_ASSERT(VALID_INT16(out[7])); out[1] = (float)(FLOAT_SCALE(L07, DCTII_8_SHIFT_1 - 1)); OI_ASSERT(VALID_INT16(out[1])); } #undef BUTTERFLY #endif /* * This function calculates the AAN DCT. Its inputs are in S16.15 format, as * returned by OI_SBC_Dequant. In practice, abs(in[x]) < 52429.0 / 1.38 * (1244918057 integer). The function it computes is an approximation to the * array defined by: * * diag(aan_s) * AAN= C2 * * or * * AAN = diag(1/aan_s) * C2 * * where C2 is as it is defined in the comment at the head of this file, and * * aan_s[i] = aan_s = 1/(2*cos(i*pi/16)) with i = 1..7, aan_s[0] = 1; * * aan_s[i] = [ 1.000 0.510 0.541 0.601 0.707 0.900 1.307 2.563 ] * * The output ranges are shown as follows: * * Let Y[0..7] = AAN * X[0..7] * * Without loss of generality, assume the input vector X consists of elements * between -1 and 1. The maximum possible value of a given output element occurs * with some particular combination of input vector elements each of which is -1 * or 1. Consider the computation of Y[i]. Y[i] = sum t=0..7 of AAN[t,i]*X[i]. Y * is maximized if the sign of X[i] matches the sign of AAN[t,i], ensuring a * positive contribution to the sum. Equivalently, one may simply sum * abs(AAN)[t,i] over t to get the maximum possible value of Y[i]. * * This yields approximately: * [8.00 10.05 9.66 8.52 8.00 5.70 4.00 2.00] * * Given the maximum magnitude sensible input value of +/-37992, this yields the * following vector of maximum output magnitudes: * * [ 303936 381820 367003 323692 303936 216555 151968 75984 ] * * Ultimately, these values must fit into 16 bit signed integers, so they must * be scaled. A non-uniform scaling helps maximize the kept precision. The * relative number of extra bits of precision maintainable with respect to the * largest value is given here: * * [ 0 0 0 0 0 0 1 2 ] * */ PRIVATE void dct2_8(SBC_BUFFER_T* RESTRICT out, int32_t const* RESTRICT in) { #define BUTTERFLY(x, y) \ x += (y); \ (y) = (x) - ((y) << 1); #define FIX_MULT_DCT(K, x) (MUL_32S_32S_HI(K, x) << 2) int32_t L00, L01, L02, L03, L04, L05, L06, L07; int32_t L25; int32_t in0, in1, in2, in3; int32_t in4, in5, in6, in7; #if DCTII_8_SHIFT_IN != 0 in0 = SCALE(in[0], DCTII_8_SHIFT_IN); in1 = SCALE(in[1], DCTII_8_SHIFT_IN); in2 = SCALE(in[2], DCTII_8_SHIFT_IN); in3 = SCALE(in[3], DCTII_8_SHIFT_IN); in4 = SCALE(in[4], DCTII_8_SHIFT_IN); in5 = SCALE(in[5], DCTII_8_SHIFT_IN); in6 = SCALE(in[6], DCTII_8_SHIFT_IN); in7 = SCALE(in[7], DCTII_8_SHIFT_IN); #else in0 = in[0]; in1 = in[1]; in2 = in[2]; in3 = in[3]; in4 = in[4]; in5 = in[5]; in6 = in[6]; in7 = in[7]; #endif L00 = in0 + in7; L01 = in1 + in6; L02 = in2 + in5; L03 = in3 + in4; L04 = in3 - in4; L05 = in2 - in5; L06 = in1 - in6; L07 = in0 - in7; BUTTERFLY(L00, L03); BUTTERFLY(L01, L02); L02 += L03; L02 = FIX_MULT_DCT(AAN_C4_FIX, L02); BUTTERFLY(L00, L01); out[0] = (int16_t)SCALE(L00, DCTII_8_SHIFT_0); out[4] = (int16_t)SCALE(L01, DCTII_8_SHIFT_4); BUTTERFLY(L03, L02); out[6] = (int16_t)SCALE(L02, DCTII_8_SHIFT_6); out[2] = (int16_t)SCALE(L03, DCTII_8_SHIFT_2); L04 += L05; L05 += L06; L06 += L07; L04 /= 2; L05 /= 2; L06 /= 2; L07 /= 2; L05 = FIX_MULT_DCT(AAN_C4_FIX, L05); L25 = L06 - L04; L25 = FIX_MULT_DCT(AAN_C6_FIX, L25); L04 = FIX_MULT_DCT(AAN_Q0_FIX, L04); L04 -= L25; L06 = FIX_MULT_DCT(AAN_Q1_FIX, L06); L06 -= L25; BUTTERFLY(L07, L05); BUTTERFLY(L05, L04); out[3] = (int16_t)SCALE(L04, DCTII_8_SHIFT_3 - 1); out[5] = (int16_t)SCALE(L05, DCTII_8_SHIFT_5 - 1); BUTTERFLY(L07, L06); out[7] = (int16_t)SCALE(L06, DCTII_8_SHIFT_7 - 1); out[1] = (int16_t)SCALE(L07, DCTII_8_SHIFT_1 - 1); #undef BUTTERFLY #ifdef DEBUG_DCT { float float_out[8]; float_dct2_8(float_out, in); } #endif } /**@}*/