ref: 3d28ff98039134325cf689d8d08996fc8dabb225
dir: /vp9/encoder/ppc/vp9_quantize_vsx.c/
/* * Copyright (c) 2018 The WebM 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. */ #include "./vpx_config.h" #include "./vp9_rtcd.h" #include "vpx_dsp/ppc/types_vsx.h" // Multiply the packed 16-bit integers in a and b, producing intermediate 32-bit // integers, and return the high 16 bits of the intermediate integers. // (a * b) >> 16 // Note: Because this is done in 2 operations, a and b cannot both be UINT16_MIN static INLINE int16x8_t vec_mulhi(int16x8_t a, int16x8_t b) { // madds does ((A * B) >> 15) + C, we need >> 16, so we perform an extra right // shift. return vec_sra(vec_madds(a, b, vec_zeros_s16), vec_ones_u16); } // Negate 16-bit integers in a when the corresponding signed 16-bit // integer in b is negative. static INLINE int16x8_t vec_sign(int16x8_t a, int16x8_t b) { const int16x8_t mask = vec_sra(b, vec_shift_sign_s16); return vec_xor(vec_add(a, mask), mask); } // Compare packed 16-bit integers across a, and return the maximum value in // every element. Returns a vector containing the biggest value across vector a. static INLINE int16x8_t vec_max_across(int16x8_t a) { a = vec_max(a, vec_perm(a, a, vec_perm64)); a = vec_max(a, vec_perm(a, a, vec_perm32)); return vec_max(a, vec_perm(a, a, vec_perm16)); } void vp9_quantize_fp_vsx(const tran_low_t *coeff_ptr, intptr_t n_coeffs, int skip_block, const int16_t *round_ptr, const int16_t *quant_ptr, tran_low_t *qcoeff_ptr, tran_low_t *dqcoeff_ptr, const int16_t *dequant_ptr, uint16_t *eob_ptr, const int16_t *scan, const int16_t *iscan) { int16x8_t qcoeff0, qcoeff1, dqcoeff0, dqcoeff1, eob; bool16x8_t zero_coeff0, zero_coeff1; int16x8_t round = vec_vsx_ld(0, round_ptr); int16x8_t quant = vec_vsx_ld(0, quant_ptr); int16x8_t dequant = vec_vsx_ld(0, dequant_ptr); int16x8_t coeff0 = vec_vsx_ld(0, coeff_ptr); int16x8_t coeff1 = vec_vsx_ld(16, coeff_ptr); int16x8_t scan0 = vec_vsx_ld(0, iscan); int16x8_t scan1 = vec_vsx_ld(16, iscan); (void)scan; (void)skip_block; assert(!skip_block); // First set of 8 coeff starts with DC + 7 AC qcoeff0 = vec_mulhi(vec_vaddshs(vec_abs(coeff0), round), quant); zero_coeff0 = vec_cmpeq(qcoeff0, vec_zeros_s16); qcoeff0 = vec_sign(qcoeff0, coeff0); vec_vsx_st(qcoeff0, 0, qcoeff_ptr); dqcoeff0 = vec_mladd(qcoeff0, dequant, vec_zeros_s16); vec_vsx_st(dqcoeff0, 0, dqcoeff_ptr); // Remove DC value from round and quant round = vec_splat(round, 1); quant = vec_splat(quant, 1); // Remove DC value from dequant dequant = vec_splat(dequant, 1); // Second set of 8 coeff starts with (all AC) qcoeff1 = vec_mulhi(vec_vaddshs(vec_abs(coeff1), round), quant); zero_coeff1 = vec_cmpeq(qcoeff1, vec_zeros_s16); qcoeff1 = vec_sign(qcoeff1, coeff1); vec_vsx_st(qcoeff1, 16, qcoeff_ptr); dqcoeff1 = vec_mladd(qcoeff1, dequant, vec_zeros_s16); vec_vsx_st(dqcoeff1, 16, dqcoeff_ptr); eob = vec_max(vec_or(scan0, zero_coeff0), vec_or(scan1, zero_coeff1)); // We quantize 16 coeff up front (enough for a 4x4) and process 24 coeff per // loop iteration. // for 8x8: 16 + 2 x 24 = 64 // for 16x16: 16 + 10 x 24 = 256 if (n_coeffs > 16) { int16x8_t coeff2, qcoeff2, dqcoeff2, eob2, scan2; bool16x8_t zero_coeff2; int index = 16; int off0 = 32; int off1 = 48; int off2 = 64; do { coeff0 = vec_vsx_ld(off0, coeff_ptr); coeff1 = vec_vsx_ld(off1, coeff_ptr); coeff2 = vec_vsx_ld(off2, coeff_ptr); scan0 = vec_vsx_ld(off0, iscan); scan1 = vec_vsx_ld(off1, iscan); scan2 = vec_vsx_ld(off2, iscan); qcoeff0 = vec_mulhi(vec_vaddshs(vec_abs(coeff0), round), quant); zero_coeff0 = vec_cmpeq(qcoeff0, vec_zeros_s16); qcoeff0 = vec_sign(qcoeff0, coeff0); vec_vsx_st(qcoeff0, off0, qcoeff_ptr); dqcoeff0 = vec_mladd(qcoeff0, dequant, vec_zeros_s16); vec_vsx_st(dqcoeff0, off0, dqcoeff_ptr); qcoeff1 = vec_mulhi(vec_vaddshs(vec_abs(coeff1), round), quant); zero_coeff1 = vec_cmpeq(qcoeff1, vec_zeros_s16); qcoeff1 = vec_sign(qcoeff1, coeff1); vec_vsx_st(qcoeff1, off1, qcoeff_ptr); dqcoeff1 = vec_mladd(qcoeff1, dequant, vec_zeros_s16); vec_vsx_st(dqcoeff1, off1, dqcoeff_ptr); qcoeff2 = vec_mulhi(vec_vaddshs(vec_abs(coeff2), round), quant); zero_coeff2 = vec_cmpeq(qcoeff2, vec_zeros_s16); qcoeff2 = vec_sign(qcoeff2, coeff2); vec_vsx_st(qcoeff2, off2, qcoeff_ptr); dqcoeff2 = vec_mladd(qcoeff2, dequant, vec_zeros_s16); vec_vsx_st(dqcoeff2, off2, dqcoeff_ptr); eob = vec_max(eob, vec_or(scan0, zero_coeff0)); eob2 = vec_max(vec_or(scan1, zero_coeff1), vec_or(scan2, zero_coeff2)); eob = vec_max(eob, eob2); index += 24; off0 += 48; off1 += 48; off2 += 48; } while (index < n_coeffs); } eob = vec_max_across(eob); *eob_ptr = eob[0] + 1; } // Sets the value of a 32-bit integers to 1 when the corresponding value in a is // negative. static INLINE int32x4_t vec_is_neg(int32x4_t a) { return vec_sr(a, vec_shift_sign_s32); } // DeQuantization function used for 32x32 blocks. Quantized coeff of 32x32 // blocks are twice as big as for other block sizes. As such, using // vec_mladd results in overflow. static INLINE int16x8_t dequantize_coeff_32(int16x8_t qcoeff, int16x8_t dequant) { int32x4_t dqcoeffe = vec_mule(qcoeff, dequant); int32x4_t dqcoeffo = vec_mulo(qcoeff, dequant); // Add 1 if negative to round towards zero because the C uses division. dqcoeffe = vec_add(dqcoeffe, vec_is_neg(dqcoeffe)); dqcoeffo = vec_add(dqcoeffo, vec_is_neg(dqcoeffo)); dqcoeffe = vec_sra(dqcoeffe, vec_ones_u32); dqcoeffo = vec_sra(dqcoeffo, vec_ones_u32); return (int16x8_t)vec_perm(dqcoeffe, dqcoeffo, vec_perm_odd_even_pack); } void vp9_quantize_fp_32x32_vsx(const tran_low_t *coeff_ptr, intptr_t n_coeffs, int skip_block, const int16_t *round_ptr, const int16_t *quant_ptr, tran_low_t *qcoeff_ptr, tran_low_t *dqcoeff_ptr, const int16_t *dequant_ptr, uint16_t *eob_ptr, const int16_t *scan, const int16_t *iscan) { // In stage 1, we quantize 16 coeffs (DC + 15 AC) // In stage 2, we loop 42 times and quantize 24 coeffs per iteration // (32 * 32 - 16) / 24 = 42 int num_itr = 42; // Offsets are in bytes, 16 coeffs = 32 bytes int off0 = 32; int off1 = 48; int off2 = 64; int16x8_t qcoeff0, qcoeff1, dqcoeff0, dqcoeff1, eob; bool16x8_t mask0, mask1, zero_coeff0, zero_coeff1; int16x8_t round = vec_vsx_ld(0, round_ptr); int16x8_t quant = vec_vsx_ld(0, quant_ptr); int16x8_t dequant = vec_vsx_ld(0, dequant_ptr); int16x8_t coeff0 = vec_vsx_ld(0, coeff_ptr); int16x8_t coeff1 = vec_vsx_ld(16, coeff_ptr); int16x8_t scan0 = vec_vsx_ld(0, iscan); int16x8_t scan1 = vec_vsx_ld(16, iscan); int16x8_t thres = vec_sra(dequant, vec_splats((uint16_t)2)); int16x8_t abs_coeff0 = vec_abs(coeff0); int16x8_t abs_coeff1 = vec_abs(coeff1); (void)scan; (void)skip_block; (void)n_coeffs; assert(!skip_block); mask0 = vec_cmpge(abs_coeff0, thres); round = vec_sra(vec_add(round, vec_ones_s16), vec_ones_u16); // First set of 8 coeff starts with DC + 7 AC qcoeff0 = vec_madds(vec_vaddshs(abs_coeff0, round), quant, vec_zeros_s16); qcoeff0 = vec_and(qcoeff0, mask0); zero_coeff0 = vec_cmpeq(qcoeff0, vec_zeros_s16); qcoeff0 = vec_sign(qcoeff0, coeff0); vec_vsx_st(qcoeff0, 0, qcoeff_ptr); dqcoeff0 = dequantize_coeff_32(qcoeff0, dequant); vec_vsx_st(dqcoeff0, 0, dqcoeff_ptr); // Remove DC value from thres, round, quant and dequant thres = vec_splat(thres, 1); round = vec_splat(round, 1); quant = vec_splat(quant, 1); dequant = vec_splat(dequant, 1); mask1 = vec_cmpge(abs_coeff1, thres); // Second set of 8 coeff starts with (all AC) qcoeff1 = vec_madds(vec_vaddshs(vec_abs(coeff1), round), quant, vec_zeros_s16); qcoeff1 = vec_and(qcoeff1, mask1); zero_coeff1 = vec_cmpeq(qcoeff1, vec_zeros_s16); qcoeff1 = vec_sign(qcoeff1, coeff1); vec_vsx_st(qcoeff1, 16, qcoeff_ptr); dqcoeff1 = dequantize_coeff_32(qcoeff1, dequant); vec_vsx_st(dqcoeff1, 16, dqcoeff_ptr); eob = vec_max(vec_or(scan0, zero_coeff0), vec_or(scan1, zero_coeff1)); do { int16x8_t coeff2, abs_coeff2, qcoeff2, dqcoeff2, eob2, scan2; bool16x8_t zero_coeff2, mask2; coeff0 = vec_vsx_ld(off0, coeff_ptr); coeff1 = vec_vsx_ld(off1, coeff_ptr); coeff2 = vec_vsx_ld(off2, coeff_ptr); scan0 = vec_vsx_ld(off0, iscan); scan1 = vec_vsx_ld(off1, iscan); scan2 = vec_vsx_ld(off2, iscan); abs_coeff0 = vec_abs(coeff0); abs_coeff1 = vec_abs(coeff1); abs_coeff2 = vec_abs(coeff2); qcoeff0 = vec_madds(vec_vaddshs(abs_coeff0, round), quant, vec_zeros_s16); qcoeff1 = vec_madds(vec_vaddshs(abs_coeff1, round), quant, vec_zeros_s16); qcoeff2 = vec_madds(vec_vaddshs(abs_coeff2, round), quant, vec_zeros_s16); mask0 = vec_cmpge(abs_coeff0, thres); mask1 = vec_cmpge(abs_coeff1, thres); mask2 = vec_cmpge(abs_coeff2, thres); qcoeff0 = vec_and(qcoeff0, mask0); qcoeff1 = vec_and(qcoeff1, mask1); qcoeff2 = vec_and(qcoeff2, mask2); zero_coeff0 = vec_cmpeq(qcoeff0, vec_zeros_s16); zero_coeff1 = vec_cmpeq(qcoeff1, vec_zeros_s16); zero_coeff2 = vec_cmpeq(qcoeff2, vec_zeros_s16); qcoeff0 = vec_sign(qcoeff0, coeff0); qcoeff1 = vec_sign(qcoeff1, coeff1); qcoeff2 = vec_sign(qcoeff2, coeff2); vec_vsx_st(qcoeff0, off0, qcoeff_ptr); vec_vsx_st(qcoeff1, off1, qcoeff_ptr); vec_vsx_st(qcoeff2, off2, qcoeff_ptr); dqcoeff0 = dequantize_coeff_32(qcoeff0, dequant); dqcoeff1 = dequantize_coeff_32(qcoeff1, dequant); dqcoeff2 = dequantize_coeff_32(qcoeff2, dequant); vec_vsx_st(dqcoeff0, off0, dqcoeff_ptr); vec_vsx_st(dqcoeff1, off1, dqcoeff_ptr); vec_vsx_st(dqcoeff2, off2, dqcoeff_ptr); eob = vec_max(eob, vec_or(scan0, zero_coeff0)); eob2 = vec_max(vec_or(scan1, zero_coeff1), vec_or(scan2, zero_coeff2)); eob = vec_max(eob, eob2); off0 += 48; off1 += 48; off2 += 48; num_itr--; } while (num_itr != 0); eob = vec_max_across(eob); *eob_ptr = eob[0] + 1; }