diff options
Diffstat (limited to 'spa/plugins/audioconvert/channelmix-ops-sse.c')
| -rw-r--r-- | spa/plugins/audioconvert/channelmix-ops-sse.c | 522 |
1 files changed, 522 insertions, 0 deletions
diff --git a/spa/plugins/audioconvert/channelmix-ops-sse.c b/spa/plugins/audioconvert/channelmix-ops-sse.c new file mode 100644 index 0000000..8311fb4 --- /dev/null +++ b/spa/plugins/audioconvert/channelmix-ops-sse.c @@ -0,0 +1,522 @@ +/* Spa + * + * Copyright © 2018 Wim Taymans + * + * Permission is hereby granted, free of charge, to any person obtaining a + * copy of this software and associated documentation files (the "Software"), + * to deal in the Software without restriction, including without limitation + * the rights to use, copy, modify, merge, publish, distribute, sublicense, + * and/or sell copies of the Software, and to permit persons to whom the + * Software is furnished to do so, subject to the following conditions: + * + * The above copyright notice and this permission notice (including the next + * paragraph) shall be included in all copies or substantial portions of the + * Software. + * + * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR + * IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, + * FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL + * THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER + * LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING + * FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER + * DEALINGS IN THE SOFTWARE. + */ + +#include "channelmix-ops.h" + +#include <xmmintrin.h> + +static inline void clear_sse(float *d, uint32_t n_samples) +{ + memset(d, 0, n_samples * sizeof(float)); +} + +static inline void copy_sse(float *d, const float *s, uint32_t n_samples) +{ + spa_memcpy(d, s, n_samples * sizeof(float)); +} + +static inline void vol_sse(float *d, const float *s, float vol, uint32_t n_samples) +{ + uint32_t n, unrolled; + if (vol == 0.0f) { + clear_sse(d, n_samples); + } else if (vol == 1.0f) { + copy_sse(d, s, n_samples); + } else { + __m128 t[4]; + const __m128 v = _mm_set1_ps(vol); + + if (SPA_IS_ALIGNED(d, 16) && + SPA_IS_ALIGNED(s, 16)) + unrolled = n_samples & ~15; + else + unrolled = 0; + + for(n = 0; n < unrolled; n += 16) { + t[0] = _mm_load_ps(&s[n]); + t[1] = _mm_load_ps(&s[n+4]); + t[2] = _mm_load_ps(&s[n+8]); + t[3] = _mm_load_ps(&s[n+12]); + _mm_store_ps(&d[n], _mm_mul_ps(t[0], v)); + _mm_store_ps(&d[n+4], _mm_mul_ps(t[1], v)); + _mm_store_ps(&d[n+8], _mm_mul_ps(t[2], v)); + _mm_store_ps(&d[n+12], _mm_mul_ps(t[3], v)); + } + for(; n < n_samples; n++) + _mm_store_ss(&d[n], _mm_mul_ss(_mm_load_ss(&s[n]), v)); + } +} + +static inline void conv_sse(float *d, const float **s, float *c, uint32_t n_c, uint32_t n_samples) +{ + __m128 mi[n_c], sum[2]; + uint32_t n, j, unrolled; + bool aligned = true; + + for (j = 0; j < n_c; j++) { + mi[j] = _mm_set1_ps(c[j]); + aligned &= SPA_IS_ALIGNED(s[j], 16); + } + + if (aligned && SPA_IS_ALIGNED(d, 16)) + unrolled = n_samples & ~7; + else + unrolled = 0; + + for (n = 0; n < unrolled; n += 8) { + sum[0] = sum[1] = _mm_setzero_ps(); + for (j = 0; j < n_c; j++) { + sum[0] = _mm_add_ps(sum[0], _mm_mul_ps(_mm_load_ps(&s[j][n + 0]), mi[j])); + sum[1] = _mm_add_ps(sum[1], _mm_mul_ps(_mm_load_ps(&s[j][n + 4]), mi[j])); + } + _mm_store_ps(&d[n + 0], sum[0]); + _mm_store_ps(&d[n + 4], sum[1]); + } + for (; n < n_samples; n++) { + sum[0] = _mm_setzero_ps(); + for (j = 0; j < n_c; j++) + sum[0] = _mm_add_ss(sum[0], _mm_mul_ss(_mm_load_ss(&s[j][n]), mi[j])); + _mm_store_ss(&d[n], sum[0]); + } +} + +static inline void avg_sse(float *d, const float *s0, const float *s1, uint32_t n_samples) +{ + uint32_t n, unrolled; + __m128 half = _mm_set1_ps(0.5f); + + if (SPA_IS_ALIGNED(d, 16) && + SPA_IS_ALIGNED(s0, 16) && + SPA_IS_ALIGNED(s1, 16)) + unrolled = n_samples & ~7; + else + unrolled = 0; + + for (n = 0; n < unrolled; n += 8) { + _mm_store_ps(&d[n + 0], + _mm_mul_ps( + _mm_add_ps( + _mm_load_ps(&s0[n + 0]), + _mm_load_ps(&s1[n + 0])), + half)); + _mm_store_ps(&d[n + 4], + _mm_mul_ps( + _mm_add_ps( + _mm_load_ps(&s0[n + 4]), + _mm_load_ps(&s1[n + 4])), + half)); + } + + for (; n < n_samples; n++) + _mm_store_ss(&d[n], + _mm_mul_ss( + _mm_add_ss( + _mm_load_ss(&s0[n]), + _mm_load_ss(&s1[n])), + half)); +} + +static inline void sub_sse(float *d, const float *s0, const float *s1, uint32_t n_samples) +{ + uint32_t n, unrolled; + + if (SPA_IS_ALIGNED(d, 16) && + SPA_IS_ALIGNED(s0, 16) && + SPA_IS_ALIGNED(s1, 16)) + unrolled = n_samples & ~7; + else + unrolled = 0; + + for (n = 0; n < unrolled; n += 8) { + _mm_store_ps(&d[n + 0], + _mm_sub_ps(_mm_load_ps(&s0[n + 0]), _mm_load_ps(&s1[n + 0]))); + _mm_store_ps(&d[n + 4], + _mm_sub_ps(_mm_load_ps(&s0[n + 4]), _mm_load_ps(&s1[n + 4]))); + } + for (; n < n_samples; n++) + _mm_store_ss(&d[n], + _mm_sub_ss(_mm_load_ss(&s0[n]), _mm_load_ss(&s1[n]))); +} + +void channelmix_copy_sse(struct channelmix *mix, void * SPA_RESTRICT dst[], + const void * SPA_RESTRICT src[], uint32_t n_samples) +{ + uint32_t i, n_dst = mix->dst_chan; + float **d = (float **)dst; + const float **s = (const float **)src; + for (i = 0; i < n_dst; i++) + vol_sse(d[i], s[i], mix->matrix[i][i], n_samples); +} + +void +channelmix_f32_n_m_sse(struct channelmix *mix, void * SPA_RESTRICT dst[], + const void * SPA_RESTRICT src[], uint32_t n_samples) +{ + float **d = (float **) dst; + const float **s = (const float **) src; + uint32_t i, j, n_dst = mix->dst_chan, n_src = mix->src_chan; + + for (i = 0; i < n_dst; i++) { + float *di = d[i]; + float mj[n_src]; + const float *sj[n_src]; + uint32_t n_j = 0; + + for (j = 0; j < n_src; j++) { + if (mix->matrix[i][j] == 0.0f) + continue; + mj[n_j] = mix->matrix[i][j]; + sj[n_j++] = s[j]; + } + if (n_j == 0) { + clear_sse(di, n_samples); + } else if (n_j == 1) { + if (mix->lr4[i].active) + lr4_process(&mix->lr4[i], di, sj[0], mj[0], n_samples); + else + vol_sse(di, sj[0], mj[0], n_samples); + } else { + conv_sse(di, sj, mj, n_j, n_samples); + lr4_process(&mix->lr4[i], di, di, 1.0f, n_samples); + } + } +} + +void +channelmix_f32_2_3p1_sse(struct channelmix *mix, void * SPA_RESTRICT dst[], + const void * SPA_RESTRICT src[], uint32_t n_samples) +{ + uint32_t i, n, unrolled, n_dst = mix->dst_chan; + float **d = (float **)dst; + const float **s = (const float **)src; + const float v0 = mix->matrix[0][0]; + const float v1 = mix->matrix[1][1]; + const float v2 = (mix->matrix[2][0] + mix->matrix[2][1]) * 0.5f; + const float v3 = (mix->matrix[3][0] + mix->matrix[3][1]) * 0.5f; + + if (SPA_FLAG_IS_SET(mix->flags, CHANNELMIX_FLAG_ZERO)) { + for (i = 0; i < n_dst; i++) + clear_sse(d[i], n_samples); + } + else { + if (mix->widen == 0.0f) { + vol_sse(d[0], s[0], v0, n_samples); + vol_sse(d[1], s[1], v1, n_samples); + avg_sse(d[2], s[0], s[1], n_samples); + } else { + const __m128 mv0 = _mm_set1_ps(mix->matrix[0][0]); + const __m128 mv1 = _mm_set1_ps(mix->matrix[1][1]); + const __m128 mw = _mm_set1_ps(mix->widen); + const __m128 mh = _mm_set1_ps(0.5f); + __m128 t0[1], t1[1], w[1], c[1]; + + if (SPA_IS_ALIGNED(s[0], 16) && + SPA_IS_ALIGNED(s[1], 16) && + SPA_IS_ALIGNED(d[0], 16) && + SPA_IS_ALIGNED(d[1], 16) && + SPA_IS_ALIGNED(d[2], 16)) + unrolled = n_samples & ~3; + else + unrolled = 0; + + for(n = 0; n < unrolled; n += 4) { + t0[0] = _mm_load_ps(&s[0][n]); + t1[0] = _mm_load_ps(&s[1][n]); + c[0] = _mm_add_ps(t0[0], t1[0]); + w[0] = _mm_mul_ps(c[0], mw); + _mm_store_ps(&d[0][n], _mm_mul_ps(_mm_sub_ps(t0[0], w[0]), mv0)); + _mm_store_ps(&d[1][n], _mm_mul_ps(_mm_sub_ps(t1[0], w[0]), mv1)); + _mm_store_ps(&d[2][n], _mm_mul_ps(c[0], mh)); + } + for (; n < n_samples; n++) { + t0[0] = _mm_load_ss(&s[0][n]); + t1[0] = _mm_load_ss(&s[1][n]); + c[0] = _mm_add_ss(t0[0], t1[0]); + w[0] = _mm_mul_ss(c[0], mw); + _mm_store_ss(&d[0][n], _mm_mul_ss(_mm_sub_ss(t0[0], w[0]), mv0)); + _mm_store_ss(&d[1][n], _mm_mul_ss(_mm_sub_ss(t1[0], w[0]), mv1)); + _mm_store_ss(&d[2][n], _mm_mul_ss(c[0], mh)); + } + } + lr4_process(&mix->lr4[3], d[3], d[2], v3, n_samples); + lr4_process(&mix->lr4[2], d[2], d[2], v2, n_samples); + } +} + +void +channelmix_f32_2_5p1_sse(struct channelmix *mix, void * SPA_RESTRICT dst[], + const void * SPA_RESTRICT src[], uint32_t n_samples) +{ + uint32_t i, n_dst = mix->dst_chan; + float **d = (float **)dst; + const float **s = (const float **)src; + const float v4 = mix->matrix[4][0]; + const float v5 = mix->matrix[5][1]; + + if (SPA_FLAG_IS_SET(mix->flags, CHANNELMIX_FLAG_ZERO)) { + for (i = 0; i < n_dst; i++) + clear_sse(d[i], n_samples); + } + else { + channelmix_f32_2_3p1_sse(mix, dst, src, n_samples); + + if (mix->upmix != CHANNELMIX_UPMIX_PSD) { + vol_sse(d[4], s[0], v4, n_samples); + vol_sse(d[5], s[1], v5, n_samples); + } else { + sub_sse(d[4], s[0], s[1], n_samples); + + delay_convolve_run(mix->buffer[1], &mix->pos[1], BUFFER_SIZE, mix->delay, + mix->taps, mix->n_taps, d[5], d[4], -v5, n_samples); + delay_convolve_run(mix->buffer[0], &mix->pos[0], BUFFER_SIZE, mix->delay, + mix->taps, mix->n_taps, d[4], d[4], v4, n_samples); + } + } +} + +void +channelmix_f32_2_7p1_sse(struct channelmix *mix, void * SPA_RESTRICT dst[], + const void * SPA_RESTRICT src[], uint32_t n_samples) +{ + uint32_t i, n_dst = mix->dst_chan; + float **d = (float **)dst; + const float **s = (const float **)src; + const float v4 = mix->matrix[4][0]; + const float v5 = mix->matrix[5][1]; + const float v6 = mix->matrix[6][0]; + const float v7 = mix->matrix[7][1]; + + if (SPA_FLAG_IS_SET(mix->flags, CHANNELMIX_FLAG_ZERO)) { + for (i = 0; i < n_dst; i++) + clear_sse(d[i], n_samples); + } + else { + channelmix_f32_2_3p1_sse(mix, dst, src, n_samples); + + vol_sse(d[4], s[0], v4, n_samples); + vol_sse(d[5], s[1], v5, n_samples); + + if (mix->upmix != CHANNELMIX_UPMIX_PSD) { + vol_sse(d[6], s[0], v6, n_samples); + vol_sse(d[7], s[1], v7, n_samples); + } else { + sub_sse(d[6], s[0], s[1], n_samples); + + delay_convolve_run(mix->buffer[1], &mix->pos[1], BUFFER_SIZE, mix->delay, + mix->taps, mix->n_taps, d[7], d[6], -v7, n_samples); + delay_convolve_run(mix->buffer[0], &mix->pos[0], BUFFER_SIZE, mix->delay, + mix->taps, mix->n_taps, d[6], d[6], v6, n_samples); + } + } +} +/* FL+FR+FC+LFE -> FL+FR */ +void +channelmix_f32_3p1_2_sse(struct channelmix *mix, void * SPA_RESTRICT dst[], + const void * SPA_RESTRICT src[], uint32_t n_samples) +{ + float **d = (float **) dst; + const float **s = (const float **) src; + const float m0 = mix->matrix[0][0]; + const float m1 = mix->matrix[1][1]; + const float m2 = (mix->matrix[0][2] + mix->matrix[1][2]) * 0.5f; + const float m3 = (mix->matrix[0][3] + mix->matrix[1][3]) * 0.5f; + + if (m0 == 0.0f && m1 == 0.0f && m2 == 0.0f && m3 == 0.0f) { + clear_sse(d[0], n_samples); + clear_sse(d[1], n_samples); + } + else { + uint32_t n, unrolled; + const __m128 v0 = _mm_set1_ps(m0); + const __m128 v1 = _mm_set1_ps(m1); + const __m128 clev = _mm_set1_ps(m2); + const __m128 llev = _mm_set1_ps(m3); + __m128 ctr; + + if (SPA_IS_ALIGNED(s[0], 16) && + SPA_IS_ALIGNED(s[1], 16) && + SPA_IS_ALIGNED(s[2], 16) && + SPA_IS_ALIGNED(s[3], 16) && + SPA_IS_ALIGNED(d[0], 16) && + SPA_IS_ALIGNED(d[1], 16)) + unrolled = n_samples & ~3; + else + unrolled = 0; + + for(n = 0; n < unrolled; n += 4) { + ctr = _mm_add_ps( + _mm_mul_ps(_mm_load_ps(&s[2][n]), clev), + _mm_mul_ps(_mm_load_ps(&s[3][n]), llev)); + _mm_store_ps(&d[0][n], _mm_add_ps(_mm_mul_ps(_mm_load_ps(&s[0][n]), v0), ctr)); + _mm_store_ps(&d[1][n], _mm_add_ps(_mm_mul_ps(_mm_load_ps(&s[1][n]), v1), ctr)); + } + for(; n < n_samples; n++) { + ctr = _mm_add_ss(_mm_mul_ss(_mm_load_ss(&s[2][n]), clev), + _mm_mul_ss(_mm_load_ss(&s[3][n]), llev)); + _mm_store_ss(&d[0][n], _mm_add_ss(_mm_mul_ss(_mm_load_ss(&s[0][n]), v0), ctr)); + _mm_store_ss(&d[1][n], _mm_add_ss(_mm_mul_ss(_mm_load_ss(&s[1][n]), v1), ctr)); + } + } +} + +/* FL+FR+FC+LFE+SL+SR -> FL+FR */ +void +channelmix_f32_5p1_2_sse(struct channelmix *mix, void * SPA_RESTRICT dst[], + const void * SPA_RESTRICT src[], uint32_t n_samples) +{ + uint32_t n, unrolled; + float **d = (float **) dst; + const float **s = (const float **) src; + const float m00 = mix->matrix[0][0]; + const float m11 = mix->matrix[1][1]; + const __m128 clev = _mm_set1_ps((mix->matrix[0][2] + mix->matrix[1][2]) * 0.5f); + const __m128 llev = _mm_set1_ps((mix->matrix[0][3] + mix->matrix[1][3]) * 0.5f); + const __m128 slev0 = _mm_set1_ps(mix->matrix[0][4]); + const __m128 slev1 = _mm_set1_ps(mix->matrix[1][5]); + __m128 in, ctr; + + if (SPA_IS_ALIGNED(s[0], 16) && + SPA_IS_ALIGNED(s[1], 16) && + SPA_IS_ALIGNED(s[2], 16) && + SPA_IS_ALIGNED(s[3], 16) && + SPA_IS_ALIGNED(s[4], 16) && + SPA_IS_ALIGNED(s[5], 16) && + SPA_IS_ALIGNED(d[0], 16) && + SPA_IS_ALIGNED(d[1], 16)) + unrolled = n_samples & ~3; + else + unrolled = 0; + + if (SPA_FLAG_IS_SET(mix->flags, CHANNELMIX_FLAG_ZERO)) { + clear_sse(d[0], n_samples); + clear_sse(d[1], n_samples); + } + else { + const __m128 v0 = _mm_set1_ps(m00); + const __m128 v1 = _mm_set1_ps(m11); + for(n = 0; n < unrolled; n += 4) { + ctr = _mm_add_ps(_mm_mul_ps(_mm_load_ps(&s[2][n]), clev), + _mm_mul_ps(_mm_load_ps(&s[3][n]), llev)); + in = _mm_mul_ps(_mm_load_ps(&s[4][n]), slev0); + in = _mm_add_ps(in, ctr); + in = _mm_add_ps(in, _mm_mul_ps(_mm_load_ps(&s[0][n]), v0)); + _mm_store_ps(&d[0][n], in); + in = _mm_mul_ps(_mm_load_ps(&s[5][n]), slev1); + in = _mm_add_ps(in, ctr); + in = _mm_add_ps(in, _mm_mul_ps(_mm_load_ps(&s[1][n]), v1)); + _mm_store_ps(&d[1][n], in); + } + for(; n < n_samples; n++) { + ctr = _mm_mul_ss(_mm_load_ss(&s[2][n]), clev); + ctr = _mm_add_ss(ctr, _mm_mul_ss(_mm_load_ss(&s[3][n]), llev)); + in = _mm_mul_ss(_mm_load_ss(&s[4][n]), slev0); + in = _mm_add_ss(in, ctr); + in = _mm_add_ss(in, _mm_mul_ss(_mm_load_ss(&s[0][n]), v0)); + _mm_store_ss(&d[0][n], in); + in = _mm_mul_ss(_mm_load_ss(&s[5][n]), slev1); + in = _mm_add_ss(in, ctr); + in = _mm_add_ss(in, _mm_mul_ss(_mm_load_ss(&s[1][n]), v1)); + _mm_store_ss(&d[1][n], in); + } + } +} + +/* FL+FR+FC+LFE+SL+SR -> FL+FR+FC+LFE*/ +void +channelmix_f32_5p1_3p1_sse(struct channelmix *mix, void * SPA_RESTRICT dst[], + const void * SPA_RESTRICT src[], uint32_t n_samples) +{ + uint32_t i, n, unrolled, n_dst = mix->dst_chan; + float **d = (float **) dst; + const float **s = (const float **) src; + + if (SPA_IS_ALIGNED(s[0], 16) && + SPA_IS_ALIGNED(s[1], 16) && + SPA_IS_ALIGNED(s[2], 16) && + SPA_IS_ALIGNED(s[3], 16) && + SPA_IS_ALIGNED(s[4], 16) && + SPA_IS_ALIGNED(s[5], 16) && + SPA_IS_ALIGNED(d[0], 16) && + SPA_IS_ALIGNED(d[1], 16) && + SPA_IS_ALIGNED(d[2], 16) && + SPA_IS_ALIGNED(d[3], 16)) + unrolled = n_samples & ~3; + else + unrolled = 0; + + if (SPA_FLAG_IS_SET(mix->flags, CHANNELMIX_FLAG_ZERO)) { + for (i = 0; i < n_dst; i++) + clear_sse(d[i], n_samples); + } + else { + const __m128 v0 = _mm_set1_ps(mix->matrix[0][0]); + const __m128 v1 = _mm_set1_ps(mix->matrix[1][1]); + const __m128 slev0 = _mm_set1_ps(mix->matrix[0][4]); + const __m128 slev1 = _mm_set1_ps(mix->matrix[1][5]); + + for(n = 0; n < unrolled; n += 4) { + _mm_store_ps(&d[0][n], _mm_add_ps( + _mm_mul_ps(_mm_load_ps(&s[0][n]), v0), + _mm_mul_ps(_mm_load_ps(&s[4][n]), slev0))); + + _mm_store_ps(&d[1][n], _mm_add_ps( + _mm_mul_ps(_mm_load_ps(&s[1][n]), v1), + _mm_mul_ps(_mm_load_ps(&s[5][n]), slev1))); + } + for(; n < n_samples; n++) { + _mm_store_ss(&d[0][n], _mm_add_ss( + _mm_mul_ss(_mm_load_ss(&s[0][n]), v0), + _mm_mul_ss(_mm_load_ss(&s[4][n]), slev0))); + + _mm_store_ss(&d[1][n], _mm_add_ss( + _mm_mul_ss(_mm_load_ss(&s[1][n]), v1), + _mm_mul_ss(_mm_load_ss(&s[5][n]), slev1))); + } + vol_sse(d[2], s[2], mix->matrix[2][2], n_samples); + vol_sse(d[3], s[3], mix->matrix[3][3], n_samples); + } +} + +/* FL+FR+FC+LFE+SL+SR -> FL+FR+RL+RR*/ +void +channelmix_f32_5p1_4_sse(struct channelmix *mix, void * SPA_RESTRICT dst[], + const void * SPA_RESTRICT src[], uint32_t n_samples) +{ + uint32_t i, n_dst = mix->dst_chan; + float **d = (float **) dst; + const float **s = (const float **) src; + const float v4 = mix->matrix[2][4]; + const float v5 = mix->matrix[3][5]; + + if (SPA_FLAG_IS_SET(mix->flags, CHANNELMIX_FLAG_ZERO)) { + for (i = 0; i < n_dst; i++) + clear_sse(d[i], n_samples); + } + else { + channelmix_f32_3p1_2_sse(mix, dst, src, n_samples); + + vol_sse(d[2], s[4], v4, n_samples); + vol_sse(d[3], s[5], v5, n_samples); + } +} |