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Transfusion/wavwrite_sine.c

Created October 5, 2022 17:42
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wavwrite_sine.c
/*Compiles with gcc -Wall -O2 -o wavwrite wavwrite.c*/
// Modified from https://stackoverflow.com/questions/23030980/creating-a-stereo-wav-file-using-c
#include <stdio.h>
#include <stdlib.h>
#include <stdint.h>
#include <limits.h>
#include <math.h>
/*
The header of a wav file Based on:
https://ccrma.stanford.edu/courses/422/projects/WaveFormat/
*/
typedef struct wavfile_header_s
{
char ChunkID[4]; /* 4 */
int32_t ChunkSize; /* 4 */
char Format[4]; /* 4 */
char Subchunk1ID[4]; /* 4 */
int32_t Subchunk1Size; /* 4 */
int16_t AudioFormat; /* 2 */
int16_t NumChannels; /* 2 */
int32_t SampleRate; /* 4 */
int32_t ByteRate; /* 4 */
int16_t BlockAlign; /* 2 */
int16_t BitsPerSample; /* 2 */
char Subchunk2ID[4];
int32_t Subchunk2Size;
} wavfile_header_t;
/*Standard values for CD-quality audio*/
#define SUBCHUNK1SIZE (16)
#define AUDIO_FORMAT (1) /*For PCM*/
#define NUM_CHANNELS (2)
#define SAMPLE_RATE (44100)
#define BITS_PER_SAMPLE (16)
#define BYTE_RATE (SAMPLE_RATE * NUM_CHANNELS * BITS_PER_SAMPLE / 8)
#define BLOCK_ALIGN (NUM_CHANNELS * BITS_PER_SAMPLE / 8)
/*Return 0 on success and -1 on failure*/
int write_PCM16_stereo_header(FILE *file_p,
int32_t SampleRate,
int32_t FrameCount)
{
int ret;
wavfile_header_t wav_header;
int32_t subchunk2_size;
int32_t chunk_size;
size_t write_count;
subchunk2_size = FrameCount * NUM_CHANNELS * BITS_PER_SAMPLE / 8;
chunk_size = 4 + (8 + SUBCHUNK1SIZE) + (8 + subchunk2_size);
wav_header.ChunkID[0] = 'R';
wav_header.ChunkID[1] = 'I';
wav_header.ChunkID[2] = 'F';
wav_header.ChunkID[3] = 'F';
wav_header.ChunkSize = chunk_size;
wav_header.Format[0] = 'W';
wav_header.Format[1] = 'A';
wav_header.Format[2] = 'V';
wav_header.Format[3] = 'E';
wav_header.Subchunk1ID[0] = 'f';
wav_header.Subchunk1ID[1] = 'm';
wav_header.Subchunk1ID[2] = 't';
wav_header.Subchunk1ID[3] = ' ';
wav_header.Subchunk1Size = SUBCHUNK1SIZE;
wav_header.AudioFormat = AUDIO_FORMAT;
wav_header.NumChannels = NUM_CHANNELS;
wav_header.SampleRate = SampleRate;
wav_header.ByteRate = BYTE_RATE;
wav_header.BlockAlign = BLOCK_ALIGN;
wav_header.BitsPerSample = BITS_PER_SAMPLE;
wav_header.Subchunk2ID[0] = 'd';
wav_header.Subchunk2ID[1] = 'a';
wav_header.Subchunk2ID[2] = 't';
wav_header.Subchunk2ID[3] = 'a';
wav_header.Subchunk2Size = subchunk2_size;
write_count = fwrite( &wav_header,
sizeof(wavfile_header_t), 1,
file_p);
ret = (1 != write_count)? -1 : 0;
return ret;
}
/*Data structure to hold a single frame with two channels*/
typedef struct PCM16_stereo_s
{
int16_t left;
int16_t right;
} PCM16_stereo_t;
PCM16_stereo_t *allocate_PCM16_stereo_buffer(int32_t FrameCount)
{
return (PCM16_stereo_t *)malloc(sizeof(PCM16_stereo_t) * FrameCount);
}
/*Return the number of audio frames sucessfully written*/
size_t write_PCM16wav_data(FILE* file_p,
int32_t FrameCount,
PCM16_stereo_t *buffer_p)
{
size_t ret;
ret = fwrite( buffer_p,
sizeof(PCM16_stereo_t), FrameCount,
file_p);
return ret;
}
/*Generate two saw-tooth signals at two frequencies and amplitudes*/
int generate_dual_sawtooth( double frequency1,
double amplitude1,
double frequency2,
double amplitude2,
int32_t SampleRate,
int32_t FrameCount,
PCM16_stereo_t *buffer_p)
{
int ret = 0;
double SampleRate_d = (double)SampleRate;
double SamplePeriod = 1.0 / SampleRate_d;
double Period1, Period2;
double phase1, phase2;
double Slope1, Slope2;
int32_t k;
/*Check for the violation of the Nyquist limit*/
if( (frequency1*2 >= SampleRate_d) || (frequency2*2 >= SampleRate_d) )
{
ret = -1;
goto error0;
}
/*Compute the period*/
// Period1 = 1.0 / frequency1;
// Period2 = 1.0 / frequency2;
/*Compute the slope*/
// Slope1 = amplitude1 / Period1;
// Slope2 = amplitude2 / Period2;
for(k = 0 /*, phase1 = 0.0, phase2 = 0.0*/;
k < FrameCount;
k++)
{
double value1 = amplitude1 * sin(2 * frequency1 * M_PI * (double) k / SampleRate);
double value2 = amplitude2 * sin(2 * frequency2 * M_PI * (double) k / SampleRate);
// phase1 += SamplePeriod;
// phase1 = (phase1 > Period1)? (phase1 - Period1) : phase1;
// phase2 += SamplePeriod;
// phase2 = (phase2 > Period2)? (phase2 - Period2) : phase2;
// buffer_p[k].left = (int16_t)(phase1 * Slope1);
// buffer_p[k].right = (int16_t)(phase2 * Slope2);
buffer_p[k].left = (int16_t)(value1);
buffer_p[k].right = (int16_t)(value2);
}
error0:
return ret;
}
int main(void)
{
int ret;
FILE* file_p;
double frequency1 = 493.9; /*B4*/
double amplitude1 = 0.65 * (double)SHRT_MAX;
double frequency2 = 392.0; /*G4*/
double amplitude2 = 0.75 * (double)SHRT_MAX;
double duration = 10; /*seconds*/
int32_t FrameCount = duration * SAMPLE_RATE;
PCM16_stereo_t *buffer_p = NULL;
size_t written;
/*Open the wav file*/
file_p = fopen("./sine_test_for_shoui.wav", "wb");
if(NULL == file_p)
{
perror("fopen failed in main");
ret = -1;
goto error0;
}
/*Allocate the data buffer*/
buffer_p = allocate_PCM16_stereo_buffer(FrameCount);
if(NULL == buffer_p)
{
perror("fopen failed in main");
ret = -1;
goto error1;
}
/*Fill the buffer*/
ret = generate_dual_sawtooth( frequency1,
amplitude1,
frequency2,
amplitude2,
SAMPLE_RATE,
FrameCount,
buffer_p);
if(ret < 0)
{
fprintf(stderr, "generate_dual_sawtooth failed in main\n");
ret = -1;
goto error2;
}
/*Write the wav file header*/
ret = write_PCM16_stereo_header(file_p,
SAMPLE_RATE,
FrameCount);
if(ret < 0)
{
perror("write_PCM16_stereo_header failed in main");
ret = -1;
goto error2;
}
/*Write the data out to file*/
written = write_PCM16wav_data( file_p,
FrameCount,
buffer_p);
if(written < FrameCount)
{
perror("write_PCM16wav_data failed in main");
ret = -1;
goto error2;
}
/*Free and close everything*/
error2:
free(buffer_p);
error1:
fclose(file_p);
error0:
return ret;
}
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