/* Spa */ /* SPDX-FileCopyrightText: Copyright © 2018 Wim Taymans */ /* SPDX-License-Identifier: MIT */ #include #include "channelmix-ops.h" static inline void clear_c(float *d, uint32_t n_samples) { memset(d, 0, n_samples * sizeof(float)); } static inline void copy_c(float *d, const float *s, uint32_t n_samples) { if (d != s) spa_memcpy(d, s, n_samples * sizeof(float)); } static inline void vol_c(float *d, const float *s, float vol, uint32_t n_samples) { uint32_t n; if (vol == 0.0f) { clear_c(d, n_samples); } else if (vol == 1.0f) { copy_c(d, s, n_samples); } else { for (n = 0; n < n_samples; n++) d[n] = s[n] * vol; } } static inline void conv_c(float *d, const float **s, float *c, uint32_t n_c, uint32_t n_samples) { uint32_t n, j; for (n = 0; n < n_samples; n++) { float sum = 0.0f; for (j = 0; j < n_c; j++) sum += s[j][n] * c[j]; d[n] = sum; } } static inline void avg_c(float *d, const float *s0, const float *s1, uint32_t n_samples) { uint32_t n; for (n = 0; n < n_samples; n++) d[n] = (s0[n] + s1[n]) * 0.5f; } static inline void sub_c(float *d, const float *s0, const float *s1, uint32_t n_samples) { uint32_t n; for (n = 0; n < n_samples; n++) d[n] = s0[n] - s1[n]; } void channelmix_copy_c(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_c(d[i], s[i], mix->matrix[i][i], n_samples); } static void lr4_process_c(struct lr4 *lr4, float *dst, const float *src, const float vol, int samples) { float x1 = lr4->x1; float x2 = lr4->x2; float y1 = lr4->y1; float y2 = lr4->y2; float b0 = lr4->bq.b0; float b1 = lr4->bq.b1; float b2 = lr4->bq.b2; float a1 = lr4->bq.a1; float a2 = lr4->bq.a2; float x, y, z; int i; if (vol == 0.0f || !lr4->active) { vol_c(dst, src, vol, samples); return; } for (i = 0; i < samples; i++) { x = src[i]; y = b0 * x + x1; x1 = b1 * x - a1 * y + x2; x2 = b2 * x - a2 * y; z = b0 * y + y1; y1 = b1 * y - a1 * z + y2; y2 = b2 * y - a2 * z; dst[i] = z * vol; } #define F(x) (-FLT_MIN < (x) && (x) < FLT_MIN ? 0.0f : (x)) lr4->x1 = F(x1); lr4->x2 = F(x2); lr4->y1 = F(y1); lr4->y2 = F(y2); #undef F } static inline void delay_convolve_run_c(float *buffer, uint32_t *pos, uint32_t n_buffer, uint32_t delay, const float *taps, uint32_t n_taps, float *dst, const float *src, const float vol, uint32_t n_samples) { uint32_t i, j; uint32_t w = *pos; uint32_t o = n_buffer - delay - n_taps-1; if (n_taps == 1) { for (i = 0; i < n_samples; i++) { buffer[w] = buffer[w + n_buffer] = src[i]; dst[i] = buffer[w + o] * vol; w = w + 1 >= n_buffer ? 0 : w + 1; } } else { for (i = 0; i < n_samples; i++) { float sum = 0.0f; buffer[w] = buffer[w + n_buffer] = src[i]; for (j = 0; j < n_taps; j++) sum += taps[j] * buffer[w+o+j]; dst[i] = sum * vol; w = w + 1 >= n_buffer ? 0 : w + 1; } } *pos = w; } #define _M(ch) (1UL << SPA_AUDIO_CHANNEL_ ## ch) void channelmix_f32_n_m_c(struct channelmix *mix, void * SPA_RESTRICT dst[], const void * SPA_RESTRICT src[], uint32_t n_samples) { uint32_t i, j, n_dst = mix->dst_chan, n_src = mix->src_chan; float **d = (float **) dst; const float **s = (const float **) src; if (SPA_FLAG_IS_SET(mix->flags, CHANNELMIX_FLAG_ZERO)) { for (i = 0; i < n_dst; i++) clear_c(d[i], n_samples); } else if (SPA_FLAG_IS_SET(mix->flags, CHANNELMIX_FLAG_COPY)) { uint32_t copy = SPA_MIN(n_dst, n_src); for (i = 0; i < copy; i++) copy_c(d[i], s[i], n_samples); for (; i < n_dst; i++) clear_c(d[i], n_samples); } else { 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_c(di, n_samples); } else if (n_j == 1) { lr4_process_c(&mix->lr4[i], di, sj[0], mj[0], n_samples); } else { conv_c(di, sj, mj, n_j, n_samples); lr4_process_c(&mix->lr4[i], di, di, 1.0f, n_samples); } } } } #define MASK_MONO _M(FC)|_M(MONO)|_M(UNKNOWN) #define MASK_STEREO _M(FL)|_M(FR)|_M(UNKNOWN) void channelmix_f32_1_2_c(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 v0 = mix->matrix[0][0]; const float v1 = mix->matrix[1][0]; vol_c(d[0], s[0], v0, n_samples); vol_c(d[1], s[0], v1, n_samples); } void channelmix_f32_2_1_c(struct channelmix *mix, void * SPA_RESTRICT dst[], const void * SPA_RESTRICT src[], uint32_t n_samples) { uint32_t n; float **d = (float **)dst; const float **s = (const float **)src; const float v0 = mix->matrix[0][0]; const float v1 = mix->matrix[0][1]; if (SPA_FLAG_IS_SET(mix->flags, CHANNELMIX_FLAG_ZERO)) { clear_c(d[0], n_samples); } else if (SPA_FLAG_IS_SET(mix->flags, CHANNELMIX_FLAG_EQUAL)) { for (n = 0; n < n_samples; n++) d[0][n] = (s[0][n] + s[1][n]) * v0; } else { for (n = 0; n < n_samples; n++) d[0][n] = s[0][n] * v0 + s[1][n] * v1; } } void channelmix_f32_4_1_c(struct channelmix *mix, void * SPA_RESTRICT dst[], const void * SPA_RESTRICT src[], uint32_t n_samples) { uint32_t n; float **d = (float **)dst; const float **s = (const float **)src; const float v0 = mix->matrix[0][0]; const float v1 = mix->matrix[0][1]; const float v2 = mix->matrix[0][2]; const float v3 = mix->matrix[0][3]; if (SPA_FLAG_IS_SET(mix->flags, CHANNELMIX_FLAG_ZERO)) { clear_c(d[0], n_samples); } else if (SPA_FLAG_IS_SET(mix->flags, CHANNELMIX_FLAG_EQUAL)) { for (n = 0; n < n_samples; n++) d[0][n] = (s[0][n] + s[1][n] + s[2][n] + s[3][n]) * v0; } else { for (n = 0; n < n_samples; n++) d[0][n] = s[0][n] * v0 + s[1][n] * v1 + s[2][n] * v2 + s[3][n] * v3; } } #define MASK_QUAD _M(FL)|_M(FR)|_M(RL)|_M(RR)|_M(UNKNOWN) void channelmix_f32_2_4_c(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 v0 = mix->matrix[0][0]; const float v1 = mix->matrix[1][1]; const float v2 = mix->matrix[2][0]; const float v3 = mix->matrix[3][1]; if (SPA_FLAG_IS_SET(mix->flags, CHANNELMIX_FLAG_ZERO)) { for (i = 0; i < n_dst; i++) clear_c(d[i], n_samples); } else { vol_c(d[0], s[0], v0, n_samples); vol_c(d[1], s[1], v1, n_samples); if (mix->upmix != CHANNELMIX_UPMIX_PSD) { vol_c(d[2], s[0], v2, n_samples); vol_c(d[3], s[1], v3, n_samples); } else { sub_c(d[2], s[0], s[1], n_samples); delay_convolve_run_c(mix->buffer[1], &mix->pos[1], BUFFER_SIZE, mix->delay, mix->taps, mix->n_taps, d[3], d[2], -v3, n_samples); delay_convolve_run_c(mix->buffer[0], &mix->pos[0], BUFFER_SIZE, mix->delay, mix->taps, mix->n_taps, d[2], d[2], v2, n_samples); } } } #define MASK_3_1 _M(FL)|_M(FR)|_M(FC)|_M(LFE) void channelmix_f32_2_3p1_c(struct channelmix *mix, void * SPA_RESTRICT dst[], const void * SPA_RESTRICT src[], uint32_t n_samples) { uint32_t i, n, 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_c(d[i], n_samples); } else { if (mix->widen == 0.0f) { vol_c(d[0], s[0], v0, n_samples); vol_c(d[1], s[1], v1, n_samples); avg_c(d[2], s[0], s[1], n_samples); } else { for (n = 0; n < n_samples; n++) { float c = s[0][n] + s[1][n]; float w = c * mix->widen; d[0][n] = (s[0][n] - w) * v0; d[1][n] = (s[1][n] - w) * v1; d[2][n] = c * 0.5f; } } lr4_process_c(&mix->lr4[3], d[3], d[2], v3, n_samples); lr4_process_c(&mix->lr4[2], d[2], d[2], v2, n_samples); } } #define MASK_5_1 _M(FL)|_M(FR)|_M(FC)|_M(LFE)|_M(SL)|_M(SR)|_M(RL)|_M(RR) void channelmix_f32_2_5p1_c(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_c(d[i], n_samples); } else { channelmix_f32_2_3p1_c(mix, dst, src, n_samples); if (mix->upmix != CHANNELMIX_UPMIX_PSD) { vol_c(d[4], s[0], v4, n_samples); vol_c(d[5], s[1], v5, n_samples); } else { sub_c(d[4], s[0], s[1], n_samples); delay_convolve_run_c(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_c(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_c(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_c(d[i], n_samples); } else { channelmix_f32_2_3p1_c(mix, dst, src, n_samples); vol_c(d[4], s[0], v4, n_samples); vol_c(d[5], s[1], v5, n_samples); if (mix->upmix != CHANNELMIX_UPMIX_PSD) { vol_c(d[6], s[0], v6, n_samples); vol_c(d[7], s[1], v7, n_samples); } else { sub_c(d[6], s[0], s[1], n_samples); delay_convolve_run_c(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_c(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_c(struct channelmix *mix, void * SPA_RESTRICT dst[], const void * SPA_RESTRICT src[], uint32_t n_samples) { uint32_t n; 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 clev = (mix->matrix[0][2] + mix->matrix[1][2]) * 0.5f; const float llev = (mix->matrix[0][3] + mix->matrix[1][3]) * 0.5f; if (SPA_FLAG_IS_SET(mix->flags, CHANNELMIX_FLAG_ZERO)) { clear_c(d[0], n_samples); clear_c(d[1], n_samples); } else { for (n = 0; n < n_samples; n++) { const float ctr = clev * s[2][n] + llev * s[3][n]; d[0][n] = s[0][n] * v0 + ctr; d[1][n] = s[1][n] * v1 + ctr; } } } /* FL+FR+FC+LFE+SL+SR -> FL+FR */ void channelmix_f32_5p1_2_c(struct channelmix *mix, void * SPA_RESTRICT dst[], const void * SPA_RESTRICT src[], uint32_t n_samples) { uint32_t n; 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 clev = (mix->matrix[0][2] + mix->matrix[1][2]) * 0.5f; const float llev = (mix->matrix[0][3] + mix->matrix[1][3]) * 0.5f; const float slev0 = mix->matrix[0][4]; const float slev1 = mix->matrix[1][5]; if (SPA_FLAG_IS_SET(mix->flags, CHANNELMIX_FLAG_ZERO)) { clear_c(d[0], n_samples); clear_c(d[1], n_samples); } else { for (n = 0; n < n_samples; n++) { const float ctr = clev * s[2][n] + llev * s[3][n]; d[0][n] = s[0][n] * v0 + ctr + (slev0 * s[4][n]); d[1][n] = s[1][n] * v1 + ctr + (slev1 * s[5][n]); } } } /* FL+FR+FC+LFE+SL+SR -> FL+FR+FC+LFE*/ void channelmix_f32_5p1_3p1_c(struct channelmix *mix, void * SPA_RESTRICT dst[], const void * SPA_RESTRICT src[], uint32_t n_samples) { uint32_t i, n, 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][2]; const float v3 = mix->matrix[3][3]; const float v4 = mix->matrix[0][4]; const float v5 = mix->matrix[1][5]; if (SPA_FLAG_IS_SET(mix->flags, CHANNELMIX_FLAG_ZERO)) { for (i = 0; i < n_dst; i++) clear_c(d[i], n_samples); } else { for (n = 0; n < n_samples; n++) { d[0][n] = s[0][n] * v0 + s[4][n] * v4; d[1][n] = s[1][n] * v1 + s[5][n] * v5; } vol_c(d[2], s[2], v2, n_samples); vol_c(d[3], s[3], v3, n_samples); } } /* FL+FR+FC+LFE+SL+SR -> FL+FR+RL+RR*/ void channelmix_f32_5p1_4_c(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_c(d[i], n_samples); } else { channelmix_f32_3p1_2_c(mix, dst, src, n_samples); vol_c(d[2], s[4], v4, n_samples); vol_c(d[3], s[5], v5, n_samples); } } #define MASK_7_1 _M(FL)|_M(FR)|_M(FC)|_M(LFE)|_M(SL)|_M(SR)|_M(RL)|_M(RR) /* FL+FR+FC+LFE+SL+SR+RL+RR -> FL+FR */ void channelmix_f32_7p1_2_c(struct channelmix *mix, void * SPA_RESTRICT dst[], const void * SPA_RESTRICT src[], uint32_t n_samples) { uint32_t n; 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 clev = (mix->matrix[0][2] + mix->matrix[1][2]) * 0.5f; const float llev = (mix->matrix[0][3] + mix->matrix[1][3]) * 0.5f; const float slev0 = mix->matrix[0][4]; const float slev1 = mix->matrix[1][5]; const float rlev0 = mix->matrix[0][6]; const float rlev1 = mix->matrix[1][7]; if (SPA_FLAG_IS_SET(mix->flags, CHANNELMIX_FLAG_ZERO)) { clear_c(d[0], n_samples); clear_c(d[1], n_samples); } else { for (n = 0; n < n_samples; n++) { const float ctr = clev * s[2][n] + llev * s[3][n]; d[0][n] = s[0][n] * v0 + ctr + s[4][n] * slev0 + s[6][n] * rlev0; d[1][n] = s[1][n] * v1 + ctr + s[5][n] * slev1 + s[7][n] * rlev1; } } } /* FL+FR+FC+LFE+SL+SR+RL+RR -> FL+FR+FC+LFE*/ void channelmix_f32_7p1_3p1_c(struct channelmix *mix, void * SPA_RESTRICT dst[], const void * SPA_RESTRICT src[], uint32_t n_samples) { uint32_t i, n, 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][2]; const float v3 = mix->matrix[3][3]; const float v4 = (mix->matrix[0][4] + mix->matrix[0][6]) * 0.5f; const float v5 = (mix->matrix[1][5] + mix->matrix[1][7]) * 0.5f; if (SPA_FLAG_IS_SET(mix->flags, CHANNELMIX_FLAG_ZERO)) { for (i = 0; i < n_dst; i++) clear_c(d[i], n_samples); } else { for (n = 0; n < n_samples; n++) { d[0][n] = s[0][n] * v0 + (s[4][n] + s[6][n]) * v4; d[1][n] = s[1][n] * v1 + (s[5][n] + s[7][n]) * v5; } vol_c(d[2], s[2], v2, n_samples); vol_c(d[3], s[3], v3, n_samples); } } /* FL+FR+FC+LFE+SL+SR+RL+RR -> FL+FR+RL+RR*/ void channelmix_f32_7p1_4_c(struct channelmix *mix, void * SPA_RESTRICT dst[], const void * SPA_RESTRICT src[], uint32_t n_samples) { uint32_t i, n, 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 clev = (mix->matrix[0][2] + mix->matrix[1][2]) * 0.5f; const float llev = (mix->matrix[0][3] + mix->matrix[1][3]) * 0.5f; const float slev0 = mix->matrix[2][4]; const float slev1 = mix->matrix[3][5]; const float rlev0 = mix->matrix[2][6]; const float rlev1 = mix->matrix[3][7]; if (SPA_FLAG_IS_SET(mix->flags, CHANNELMIX_FLAG_ZERO)) { for (i = 0; i < n_dst; i++) clear_c(d[i], n_samples); } else { for (n = 0; n < n_samples; n++) { const float ctr = s[2][n] * clev + s[3][n] * llev; const float sl = s[4][n] * slev0; const float sr = s[5][n] * slev1; d[0][n] = s[0][n] * v0 + ctr + sl; d[1][n] = s[1][n] * v1 + ctr + sr; d[2][n] = s[6][n] * rlev0 + sl; d[3][n] = s[7][n] * rlev1 + sr; } } }