/* Copyright (c) 2013 The Chromium OS Authors. All rights reserved. * Use of this source code is governed by a BSD-style license that can be * found in the LICENSE file. */ /* Copyright (C) 2011 Google Inc. All rights reserved. * Use of this source code is governed by a BSD-style license that can be * found in the LICENSE.WEBKIT file. */ #include <assert.h> #include <stdlib.h> #include "drc.h" #include "drc_math.h" static void set_default_parameters(struct drc *drc); static void init_data_buffer(struct drc *drc); static void init_emphasis_eq(struct drc *drc); static void init_crossover(struct drc *drc); static void init_kernel(struct drc *drc); static void free_data_buffer(struct drc *drc); static void free_emphasis_eq(struct drc *drc); static void free_kernel(struct drc *drc); struct drc *drc_new(float sample_rate) { struct drc *drc = (struct drc *)calloc(1, sizeof(struct drc)); drc->sample_rate = sample_rate; set_default_parameters(drc); return drc; } void drc_init(struct drc *drc) { init_data_buffer(drc); init_emphasis_eq(drc); init_crossover(drc); init_kernel(drc); } void drc_free(struct drc *drc) { free_kernel(drc); free_emphasis_eq(drc); free_data_buffer(drc); free(drc); } /* Allocates temporary buffers used during drc_process(). */ static void init_data_buffer(struct drc *drc) { int i; size_t size = sizeof(float) * DRC_PROCESS_MAX_FRAMES; for (i = 0; i < DRC_NUM_CHANNELS; i++) { drc->data1[i] = (float *)calloc(1, size); drc->data2[i] = (float *)calloc(1, size); } } /* Frees temporary buffers */ static void free_data_buffer(struct drc *drc) { int i; for (i = 0; i < DRC_NUM_CHANNELS; i++) { free(drc->data1[i]); free(drc->data2[i]); } } void drc_set_param(struct drc *drc, int index, unsigned paramID, float value) { assert(paramID < PARAM_LAST); if (paramID < PARAM_LAST) drc->parameters[index][paramID] = value; } static float drc_get_param(struct drc *drc, int index, unsigned paramID) { assert(paramID < PARAM_LAST); return drc->parameters[index][paramID]; } /* Initializes parameters to default values. */ static void set_default_parameters(struct drc *drc) { float nyquist = drc->sample_rate / 2; int i; for (i = 0; i < DRC_NUM_KERNELS; i++) { float *param = drc->parameters[i]; param[PARAM_THRESHOLD] = -24; /* dB */ param[PARAM_KNEE] = 30; /* dB */ param[PARAM_RATIO] = 12; /* unit-less */ param[PARAM_ATTACK] = 0.003f; /* seconds */ param[PARAM_RELEASE] = 0.250f; /* seconds */ param[PARAM_PRE_DELAY] = DRC_DEFAULT_PRE_DELAY; /* seconds */ /* Release zone values 0 -> 1. */ param[PARAM_RELEASE_ZONE1] = 0.09f; param[PARAM_RELEASE_ZONE2] = 0.16f; param[PARAM_RELEASE_ZONE3] = 0.42f; param[PARAM_RELEASE_ZONE4] = 0.98f; /* This is effectively a master volume on the compressed * signal */ param[PARAM_POST_GAIN] = 0; /* dB */ param[PARAM_ENABLED] = 0; } drc->parameters[0][PARAM_CROSSOVER_LOWER_FREQ] = 0; drc->parameters[1][PARAM_CROSSOVER_LOWER_FREQ] = 200 / nyquist; drc->parameters[2][PARAM_CROSSOVER_LOWER_FREQ] = 2000 / nyquist; /* These parameters has only one copy */ drc->parameters[0][PARAM_FILTER_STAGE_GAIN] = 4.4f; /* dB */ drc->parameters[0][PARAM_FILTER_STAGE_RATIO] = 2; drc->parameters[0][PARAM_FILTER_ANCHOR] = 15000 / nyquist; } /* Finds the zero and pole for one stage of the emphasis filter */ static void emphasis_stage_roots(float gain, float normalized_frequency, float *zero, float *pole) { float gk = 1 - gain / 20; float f1 = normalized_frequency * gk; float f2 = normalized_frequency / gk; *zero = expf(-f1 * PI_FLOAT); *pole = expf(-f2 * PI_FLOAT); } /* Calculates the biquad coefficients for two emphasis stages. */ static void emphasis_stage_pair_biquads(float gain, float f1, float f2, struct biquad *emphasis, struct biquad *deemphasis) { float z1, p1; float z2, p2; emphasis_stage_roots(gain, f1, &z1, &p1); emphasis_stage_roots(gain, f2, &z2, &p2); float b0 = 1; float b1 = -(z1 + z2); float b2 = z1 * z2; float a0 = 1; float a1 = -(p1 + p2); float a2 = p1 * p2; /* Gain compensation to make 0dB @ 0Hz */ float alpha = (a0 + a1 + a2) / (b0 + b1 + b2); emphasis->b0 = b0 * alpha; emphasis->b1 = b1 * alpha; emphasis->b2 = b2 * alpha; emphasis->a1 = a1; emphasis->a2 = a2; float beta = (b0 + b1 + b2) / (a0 + a1 + a2); deemphasis->b0 = a0 * beta; deemphasis->b1 = a1 * beta; deemphasis->b2 = a2 * beta; deemphasis->a1 = b1; deemphasis->a2 = b2; } /* Initializes the emphasis and deemphasis filter */ static void init_emphasis_eq(struct drc *drc) { struct biquad e = { 0.f, 0.f, 0.f, 0.f, 0.f, 0.f, 0.f, 0.f, 0.f }; struct biquad d = { 0.f, 0.f, 0.f, 0.f, 0.f, 0.f, 0.f, 0.f, 0.f }; int i, j; float stage_gain = drc_get_param(drc, 0, PARAM_FILTER_STAGE_GAIN); float stage_ratio = drc_get_param(drc, 0, PARAM_FILTER_STAGE_RATIO); float anchor_freq = drc_get_param(drc, 0, PARAM_FILTER_ANCHOR); drc->emphasis_eq = eq2_new(); drc->deemphasis_eq = eq2_new(); for (i = 0; i < 2; i++) { emphasis_stage_pair_biquads(stage_gain, anchor_freq, anchor_freq / stage_ratio, &e, &d); for (j = 0; j < 2; j++) { eq2_append_biquad_direct(drc->emphasis_eq, j, &e); eq2_append_biquad_direct(drc->deemphasis_eq, j, &d); } anchor_freq /= (stage_ratio * stage_ratio); } } /* Frees the emphasis and deemphasis filter */ static void free_emphasis_eq(struct drc *drc) { eq2_free(drc->emphasis_eq); eq2_free(drc->deemphasis_eq); } /* Initializes the crossover filter */ static void init_crossover(struct drc *drc) { float freq1 = drc->parameters[1][PARAM_CROSSOVER_LOWER_FREQ]; float freq2 = drc->parameters[2][PARAM_CROSSOVER_LOWER_FREQ]; crossover2_init(&drc->xo2, freq1, freq2); } /* Initializes the compressor kernels */ static void init_kernel(struct drc *drc) { int i; for (i = 0; i < DRC_NUM_KERNELS; i++) { dk_init(&drc->kernel[i], drc->sample_rate); float db_threshold = drc_get_param(drc, i, PARAM_THRESHOLD); float db_knee = drc_get_param(drc, i, PARAM_KNEE); float ratio = drc_get_param(drc, i, PARAM_RATIO); float attack_time = drc_get_param(drc, i, PARAM_ATTACK); float release_time = drc_get_param(drc, i, PARAM_RELEASE); float pre_delay_time = drc_get_param(drc, i, PARAM_PRE_DELAY); float releaseZone1 = drc_get_param(drc, i, PARAM_RELEASE_ZONE1); float releaseZone2 = drc_get_param(drc, i, PARAM_RELEASE_ZONE2); float releaseZone3 = drc_get_param(drc, i, PARAM_RELEASE_ZONE3); float releaseZone4 = drc_get_param(drc, i, PARAM_RELEASE_ZONE4); float db_post_gain = drc_get_param(drc, i, PARAM_POST_GAIN); int enabled = drc_get_param(drc, i, PARAM_ENABLED); dk_set_parameters(&drc->kernel[i], db_threshold, db_knee, ratio, attack_time, release_time, pre_delay_time, db_post_gain, releaseZone1, releaseZone2, releaseZone3, releaseZone4 ); dk_set_enabled(&drc->kernel[i], enabled); } } /* Frees the compressor kernels */ static void free_kernel(struct drc *drc) { int i; for (i = 0; i < DRC_NUM_KERNELS; i++) dk_free(&drc->kernel[i]); } // Note gcc 4.9+ with -O2 on aarch64 produces vectorized version of C // that is comparable performance, but twice as large. -O1 and -Os produce // small but slower code (4x slower than Neon). #if defined(__aarch64__) static void sum3(float *data, const float *data1, const float *data2, int n) { int count = n / 4; int i; if (count) { __asm__ __volatile( "1: \n" "ld1 {v0.4s}, [%[data1]], #16 \n" "ld1 {v1.4s}, [%[data2]], #16 \n" "ld1 {v2.4s}, [%[data]] \n" "fadd v0.4s, v0.4s, v1.4s \n" "fadd v0.4s, v0.4s, v2.4s \n" "st1 {v0.4s}, [%[data]], #16 \n" "subs %w[count], %w[count], #1 \n" "b.ne 1b \n" : /* output */ [data]"+r"(data), [data1]"+r"(data1), [data2]"+r"(data2), [count]"+r"(count) : /* input */ : /* clobber */ "v0", "v1", "v2", "memory", "cc" ); } n &= 3; for (i = 0; i < n; i++) data[i] += data1[i] + data2[i]; } #elif defined(__ARM_NEON__) static void sum3(float *data, const float *data1, const float *data2, int n) { int count = n / 4; int i; if (count) { __asm__ __volatile( "1: \n" "vld1.32 {q0}, [%[data1]]! \n" "vld1.32 {q1}, [%[data2]]! \n" "vld1.32 {q2}, [%[data]] \n" "vadd.f32 q0, q0, q1 \n" "vadd.f32 q0, q0, q2 \n" "vst1.32 {q0}, [%[data]]! \n" "subs %[count], #1 \n" "bne 1b \n" : /* output */ [data]"+r"(data), [data1]"+r"(data1), [data2]"+r"(data2), [count]"+r"(count) : /* input */ : /* clobber */ "q0", "q1", "q2", "memory", "cc" ); } n &= 3; for (i = 0; i < n; i++) data[i] += data1[i] + data2[i]; } #elif defined(__SSE3__) #include <emmintrin.h> static void sum3(float *data, const float *data1, const float *data2, int n) { __m128 x, y, z; int count = n / 4; int i; if (count) { __asm__ __volatile( "1: \n" "lddqu (%[data1]), %[x] \n" "lddqu (%[data2]), %[y] \n" "lddqu (%[data]), %[z] \n" "addps %[x], %[y] \n" "addps %[y], %[z] \n" "movdqu %[z], (%[data]) \n" "add $16, %[data1] \n" "add $16, %[data2] \n" "add $16, %[data] \n" "sub $1, %[count] \n" "jne 1b \n" : /* output */ [data]"+r"(data), [data1]"+r"(data1), [data2]"+r"(data2), [count]"+r"(count), [x]"=x"(x), [y]"=x"(y), [z]"=x"(z) : /* input */ : /* clobber */ "memory", "cc" ); } n &= 3; for (i = 0; i < n; i++) data[i] += data1[i] + data2[i]; } #else static void sum3(float *data, const float *data1, const float *data2, int n) { int i; for (i = 0; i < n; i++) data[i] += data1[i] + data2[i]; } #endif void drc_process(struct drc *drc, float **data, int frames) { int i; float **data1 = drc->data1; float **data2 = drc->data2; /* Apply pre-emphasis filter if it is not disabled. */ if (!drc->emphasis_disabled) eq2_process(drc->emphasis_eq, data[0], data[1], frames); /* Crossover */ crossover2_process(&drc->xo2, frames, data[0], data[1], data1[0], data1[1], data2[0], data2[1]); /* Apply compression to each band of the signal. The processing is * performed in place. */ dk_process(&drc->kernel[0], data, frames); dk_process(&drc->kernel[1], data1, frames); dk_process(&drc->kernel[2], data2, frames); /* Sum the three bands of signal */ for (i = 0; i < DRC_NUM_CHANNELS; i++) sum3(data[i], data1[i], data2[i], frames); /* Apply de-emphasis filter if emphasis is not disabled. */ if (!drc->emphasis_disabled) eq2_process(drc->deemphasis_eq, data[0], data[1], frames); }