alsa-utils/bat/common.h

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/*
* Copyright (C) 2013-2015 Intel Corporation
*
* This program is free software; you can redistribute it and/or modify
* it under the terms of the GNU General Public License as published by
* the Free Software Foundation; either version 2 of the License, or
* (at your option) any later version.
*
* This program is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
*/
#ifndef ATTRIBUTE_UNUSED
/** do not print warning (gcc) when function parameter is not used */
#define ATTRIBUTE_UNUSED __attribute__ ((__unused__))
#endif
#define TEMP_RECORD_FILE_NAME "/tmp/bat.wav.XXXXXX"
#define DEFAULT_DEV_NAME "default"
#define OPT_BASE 300
#define OPT_LOG (OPT_BASE + 1)
#define OPT_READFILE (OPT_BASE + 2)
#define OPT_SAVEPLAY (OPT_BASE + 3)
#define OPT_LOCAL (OPT_BASE + 4)
#define OPT_STANDALONE (OPT_BASE + 5)
#define OPT_ROUNDTRIPLATENCY (OPT_BASE + 6)
#define OPT_SNRTHD_DB (OPT_BASE + 7)
#define OPT_SNRTHD_PC (OPT_BASE + 8)
#define OPT_READCAPTURE (OPT_BASE + 9)
#define COMPOSE(a, b, c, d) ((a) | ((b)<<8) | ((c)<<16) | ((d)<<24))
#define WAV_RIFF COMPOSE('R', 'I', 'F', 'F')
#define WAV_WAVE COMPOSE('W', 'A', 'V', 'E')
#define WAV_FMT COMPOSE('f', 'm', 't', ' ')
#define WAV_DATA COMPOSE('d', 'a', 't', 'a')
#define WAV_FORMAT_PCM 1 /* PCM WAVE file encoding */
#define MAX_CHANNELS 2
#define MIN_CHANNELS 1
#define MAX_PEAKS 10
#define MAX_FRAMES (10 * 1024 * 1024)
/* Given in ms */
#define CAPTURE_DELAY 500
/* signal frequency should be less than samplerate * RATE_FACTOR */
#define RATE_FACTOR 0.4
/* valid range of samplerate: (1 - RATE_RANGE, 1 + RATE_RANGE) * samplerate */
#define RATE_RANGE 0.05
/* Given in us */
#define MAX_BUFFERTIME 500000
/* devide factor, was 4, changed to 8 to remove reduce capture overrun */
#define DIV_BUFFERTIME 8
/* margin to avoid sign inversion when generate sine wav */
#define RANGE_FACTOR 0.95
#define MAX_BUFFERSIZE 200000
#define MIN_BUFFERSIZE 32
#define MAX_PERIODSIZE 200000
#define MIN_PERIODSIZE 32
/* default period size for tinyalsa */
#define TINYALSA_PERIODSIZE 1024
#define LATENCY_TEST_NUMBER 5
#define LATENCY_TEST_TIME_LIMIT 25
#define DIV_BUFFERSIZE 2
#define EBATBASE 1000
#define ENOPEAK (EBATBASE + 1)
#define EONLYDC (EBATBASE + 2)
#define EBADPEAK (EBATBASE + 3)
#define DC_THRESHOLD 7.01
/* tolerance of detected peak = max (DELTA_HZ, DELTA_RATE * target_freq).
* If DELTA_RATE is too high, BAT may not be able to recognize negative result;
* if too low, BAT may be too sensitive and results in uncecessary failure. */
#define DELTA_RATE 0.005
#define DELTA_HZ 1
#define FOUND_DC (1<<1)
#define FOUND_WRONG_PEAK (1<<0)
/* Truncate sample frames to (1 << N), for faster FFT analysis process. The
* valid range of N is (SHIFT_MIN, SHIFT_MAX). When N increases, the analysis
* will be more time-consuming, and the result will be more accurate. */
#define SHIFT_MAX (sizeof(int) * 8 - 2)
#define SHIFT_MIN 8
/* Define SNR range in dB.
* if the noise is equal to signal, SNR = 0.0dB;
* if the noise is zero, SNR is limited by RIFF wav data width:
* 8 bit --> 20.0 * log10f (powf(2.0, 8.0)) = 48.16 dB
* 16 bit --> 20.0 * log10f (powf(2.0, 16.0)) = 96.33 dB
* 24 bit --> 20.0 * log10f (powf(2.0, 24.0)) = 144.49 dB
* 32 bit --> 20.0 * log10f (powf(2.0, 32.0)) = 192.66 dB
* so define the SNR range (0.0, 200.0) dB, value out of range is invalid. */
#define SNR_DB_INVALID -1.0
#define SNR_DB_MIN 0.0
#define SNR_DB_MAX 200.0
static inline bool snr_is_valid(float db)
{
return (db > SNR_DB_MIN && db < SNR_DB_MAX);
}
struct wav_header {
unsigned int magic; /* 'RIFF' */
unsigned int length; /* file len */
unsigned int type; /* 'WAVE' */
};
struct wav_chunk_header {
unsigned int type; /* 'data' */
unsigned int length; /* sample count */
};
struct wav_fmt {
unsigned int magic; /* 'FMT '*/
unsigned int fmt_size; /* 16 or 18 */
unsigned short format; /* see WAV_FMT_* */
unsigned short channels;
unsigned int sample_rate; /* Frequency of sample */
unsigned int bytes_p_second;
unsigned short blocks_align; /* sample size; 1 or 2 bytes */
unsigned short sample_length; /* 8, 12 or 16 bit */
};
struct chunk_fmt {
unsigned short format; /* see WAV_FMT_* */
unsigned short channels;
unsigned int sample_rate; /* Frequency of sample */
unsigned int bytes_p_second;
unsigned short blocks_align; /* sample size; 1 or 2 bytes */
unsigned short sample_length; /* 8, 12 or 16 bit */
};
struct wav_container {
struct wav_header header;
struct wav_fmt format;
struct wav_chunk_header chunk;
};
struct bat;
enum _bat_pcm_format {
BAT_PCM_FORMAT_UNKNOWN = -1,
BAT_PCM_FORMAT_S16_LE = 0,
BAT_PCM_FORMAT_S32_LE,
BAT_PCM_FORMAT_U8,
BAT_PCM_FORMAT_S24_3LE,
BAT_PCM_FORMAT_MAX
};
enum _bat_op_mode {
MODE_UNKNOWN = -1,
MODE_SINGLE = 0,
MODE_LOOPBACK,
MODE_ANALYZE_ONLY,
MODE_LAST
};
enum latency_state {
LATENCY_STATE_COMPLETE_FAILURE = -1,
LATENCY_STATE_COMPLETE_SUCCESS = 0,
LATENCY_STATE_MEASURE_FOR_1_SECOND,
LATENCY_STATE_PLAY_AND_LISTEN,
LATENCY_STATE_WAITING,
};
struct pcm {
unsigned int card_tiny;
unsigned int device_tiny;
char *device;
char *file;
enum _bat_op_mode mode;
void *(*fct)(struct bat *);
};
struct sin_generator;
struct sin_generator {
double state_real;
double state_imag;
double phasor_real;
double phasor_imag;
float frequency;
float sample_rate;
float magnitude;
};
struct roundtrip_latency {
int number;
enum latency_state state;
float result[LATENCY_TEST_NUMBER];
int final_result;
int samples;
float sum;
int threshold;
int error;
bool is_capturing;
bool is_playing;
bool xrun_error;
};
struct noise_analyzer {
int nsamples; /* number of sample */
float *source; /* single-tone to be analyzed */
float *target; /* target single-tone as standard */
float rms_tgt; /* rms of target single-tone */
float snr_db; /* snr in dB */
};
struct bat {
unsigned int rate; /* sampling rate */
int channels; /* nb of channels */
int frames; /* nb of frames */
int frame_size; /* size of frame */
int sample_size; /* size of sample */
enum _bat_pcm_format format; /* PCM format */
int buffer_size; /* buffer size in frames */
int period_size; /* period size in frames */
float sigma_k; /* threshold for peak detection */
float snr_thd_db; /* threshold for noise detection (dB) */
float target_freq[MAX_CHANNELS];
int sinus_duration; /* number of frames for playback */
char *narg; /* argument string of duration */
char *logarg; /* path name of log file */
char *debugplay; /* path name to store playback signal */
char *capturefile; /* path name for previously saved recording */
bool standalone; /* enable to bypass analysis */
bool roundtriplatency; /* enable round trip latency */
struct pcm playback;
struct pcm capture;
struct roundtrip_latency latency;
unsigned int periods_played;
unsigned int periods_total;
bool period_is_limited;
FILE *fp;
FILE *log;
FILE *err;
void (*convert_sample_to_float)(void *, float *, int);
void (*convert_float_to_sample)(float *, void *, int, int);
void *buf; /* PCM Buffer */
bool local; /* true for internal test */
};
struct analyze {
void *buf;
float *in;
float *out;
float *mag;
};
void prepare_wav_info(struct wav_container *, struct bat *);
int read_wav_header(struct bat *, char *, FILE *, bool);
int write_wav_header(FILE *, struct wav_container *, struct bat *);
int update_wav_header(struct bat *, FILE *, int);
int generate_input_data(struct bat *, void *, int, int);