**Minimal C audio generation example**

The example below generates a pure 1000k Hz sinus in raw format. At the common 44.1kHz sampling rate, it will last about 4 seconds.

main.c:

```
#include <math.h>
#include <stdio.h>
#include <stdlib.h>
#include <stdint.h>
int main(void) {
FILE *f;
const double PI2 = 2 * acos(-1.0);
const double SAMPLE_FREQ = 44100;
const unsigned int NSAMPLES = 4 * SAMPLE_FREQ;
uint16_t ampl;
uint8_t bytes[2];
unsigned int t;
f = fopen("out.raw", "wb");
for (t = 0; t < NSAMPLES; ++t) {
ampl = UINT16_MAX * 0.5 * (1.0 + sin(PI2 * t * 1000.0 / SAMPLE_FREQ));
bytes[0] = ampl >> 8;
bytes[1] = ampl & 0xFF;
fwrite(bytes, 2, sizeof(uint8_t), f);
}
fclose(f);
return EXIT_SUCCESS;
}
```

GitHub upstream.

Generate `out.raw`

:

```
gcc -std=c99 -o main main.c -lm
./main
```

Play `out.raw`

directly:

```
sudo apt-get install ffmpeg
ffplay -autoexit -f u16be -ar 44100 -ac 1 out.raw
```

or convert to a more common audio format and then play with a more common audio player:

```
ffmpeg -f u16be -ar 44100 -ac 1 -i out.raw out.flac
vlc out.flac
```

Parameters explained at: https://superuser.com/a/1063230/128124

Tested on Ubuntu 18.04.

**Canon in D in C**

Here is a more interesting synthesis example.

Outcome: https://www.youtube.com/watch?v=JISozfHATms

main.c

```
#include <math.h>
#include <stdint.h>
#include <stdio.h>
#include <stdlib.h>
typedef uint16_t point_type_t;
double PI2;
void write_ampl(FILE *f, point_type_t ampl) {
uint8_t bytes[2];
bytes[0] = ampl >> 8;
bytes[1] = ampl & 0xFF;
fwrite(bytes, 2, sizeof(uint8_t), f);
}
/* https://en.wikipedia.org/wiki/Piano_key_frequencies */
double piano_freq(unsigned int i) {
return 440.0 * pow(2, (i - 49.0) / 12.0);
}
/* Chord formed by the nth note of the piano. */
point_type_t piano_sum(unsigned int max_ampl, unsigned int time,
double sample_freq, unsigned int nargs, unsigned int *notes) {
unsigned int i;
double sum = 0;
for (i = 0 ; i < nargs; ++i)
sum += sin(PI2 * time * piano_freq(notes[i]) / sample_freq);
return max_ampl * 0.5 * (nargs + sum) / nargs;
}
enum notes {
A0 = 1, AS0, B0,
C1, C1S, D1, D1S, E1, F1, F1S, G1, G1S, A1, A1S, B1,
C2, C2S, D2, D2S, E2, F2, F2S, G2, G2S, A2, A2S, B2,
C3, C3S, D3, D3S, E3, F3, F3S, G3, G3S, A3, A3S, B3,
C4, C4S, D4, D4S, E4, F4, F4S, G4, G4S, A4, A4S, B4,
C5, C5S, D5, D5S, E5, F5, F5S, G5, G5S, A5, A5S, B5,
C6, C6S, D6, D6S, E6, F6, F6S, G6, G6S, A6, A6S, B6,
C7, C7S, D7, D7S, E7, F7, F7S, G7, G7S, A7, A7S, B7,
C8,
};
int main(void) {
FILE *f;
PI2 = 2 * acos(-1.0);
const double SAMPLE_FREQ = 44100;
point_type_t ampl;
point_type_t max_ampl = UINT16_MAX;
unsigned int t, i;
unsigned int samples_per_unit = SAMPLE_FREQ * 0.375;
unsigned int *ip[] = {
(unsigned int[]){4, 2, C3, E4},
(unsigned int[]){4, 2, G3, D4},
(unsigned int[]){4, 2, A3, C4},
(unsigned int[]){4, 2, E3, B3},
(unsigned int[]){4, 2, F3, A3},
(unsigned int[]){4, 2, C3, G3},
(unsigned int[]){4, 2, F3, A3},
(unsigned int[]){4, 2, G3, B3},
(unsigned int[]){4, 3, C3, G4, E5},
(unsigned int[]){4, 3, G3, B4, D5},
(unsigned int[]){4, 2, A3, C5},
(unsigned int[]){4, 3, E3, G4, B4},
(unsigned int[]){4, 3, F3, C4, A4},
(unsigned int[]){4, 3, C3, G4, G4},
(unsigned int[]){4, 3, F3, F4, A4},
(unsigned int[]){4, 3, G3, D4, B4},
(unsigned int[]){2, 3, C4, E4, C5},
(unsigned int[]){2, 3, C4, E4, C5},
(unsigned int[]){2, 3, G3, D4, D5},
(unsigned int[]){2, 3, G3, D4, B4},
(unsigned int[]){2, 3, A3, C4, C5},
(unsigned int[]){2, 3, A3, C4, E5},
(unsigned int[]){2, 2, E3, G5},
(unsigned int[]){2, 2, E3, G4},
(unsigned int[]){2, 3, F3, A3, A4},
(unsigned int[]){2, 3, F3, A3, F4},
(unsigned int[]){2, 3, C3, E4},
(unsigned int[]){2, 3, C3, G4},
(unsigned int[]){2, 3, F3, A3, F4},
(unsigned int[]){2, 3, F3, A3, C5},
(unsigned int[]){2, 3, G3, B3, B4},
(unsigned int[]){2, 3, G3, B3, G4},
(unsigned int[]){2, 3, C4, E4, C5},
(unsigned int[]){1, 3, C4, E4, E5},
(unsigned int[]){1, 3, C4, E4, G5},
(unsigned int[]){1, 2, G3, G5},
(unsigned int[]){1, 2, G3, A5},
(unsigned int[]){1, 2, G3, G5},
(unsigned int[]){1, 2, G3, F5},
(unsigned int[]){3, 3, A3, C4, E5},
(unsigned int[]){1, 3, A3, C4, E5},
(unsigned int[]){1, 3, E3, G3, E5},
(unsigned int[]){1, 3, E3, G3, F5},
(unsigned int[]){1, 3, E3, G3, E5},
(unsigned int[]){1, 3, E3, G3, D5},
};
f = fopen("canon.raw", "wb");
for (i = 0; i < sizeof(ip) / sizeof(int*); ++i) {
unsigned int *cur = ip[i];
unsigned int total = samples_per_unit * cur[0];
for (t = 0; t < total; ++t) {
ampl = piano_sum(max_ampl, t, SAMPLE_FREQ, cur[1], &cur[2]);
write_ampl(f, ampl);
}
}
fclose(f);
return EXIT_SUCCESS;
}
```

GitHub upstream.

For YouTube, I prepared it as:

```
wget -O canon.png https://upload.wikimedia.org/wikipedia/commons/thumb/3/35/The_C_Programming_Language_logo.svg/564px-The_C_Programming_Language_logo.svg.png
ffmpeg -loop 1 -y -i canon.png -i canon.flac -shortest -acodec copy -vcodec vp9 canon.mkv
```

as explained: https://superuser.com/questions/1041816/combine-one-image-one-audio-file-to-make-one-video-using-ffmpeg/1041818#1041818

Here is a more physics oriented view of audio generation: How is audio represented with numbers?

Tested on Ubuntu 18.04.

**Physics**

Audio is encoded as a single number for every moment in time. Compare that to a video, which needs WIDTH * HEIGHT numbers per moment in time.

This number is then converted to the linear displacement of the diaphragm of your speaker:

```
| /
| /
|-/
| | A I R
|-\
| \
| \
<-> displacement
| /
| /
|---/
| | A I R
|---\
| \
| \
<---> displacement
| /
| /
|-----/
| | A I R
|-----\
| \
| \
<-----> displacement
```

The displacement pushes air backwards and forwards, creating pressure differences, which travel through air as P-waves.

Only displacement matters: a constant signal, even if maximal, produces no sound: the diaphragm just stays at a fixed position.

The sampling frequency determines how fast the displacements should be done.

44,1kHz is a common sampling frequency because humans can hear up to 20kHz and because of the Nyquist–Shannon sampling theorem.

The sampling frequency is analogous to the FPS for video, although it has a much higher value compared to the 25 (cinema) - 144 (hardcore gaming monitors) range we commonly see for video.

**Formats**

`.raw`

is an underspecified format that contains just the amplitude bytes, and no metadata.

We have to pass a few meta-data parameters on the command line like the sampling frequency because the format does not contain that data.

There are also other uncompressed formats which contain all needed metadata, e.g. `.wav`

, see: WAV File Synthesis From Scratch - C

In practice however, most people deal exclusively with compressed formats, which make files / streaming much smaller. Some of those formats take into account characteristics of the human ear to further compress the audio in a lossy way.

**Biology**

Humans perceive sound mostly by their frequency decomposition (AKA Fourier transform).

I think this is because the inner ear has parts which resonate to different frequencies (TODO confirm).

Therefore, when synthesizing music, we think more in terms of adding up frequencies instead of points in time. This is illustrated in this example.

This leads to thinking in terms of a 1D vector between 20Hz and 20kHz for each point in time.

The mathematical Fourier transform loses the notion of time, so what we do when synthesizing is to take groups of points, and sum up frequencies for that group, and take the Fourier transform there.

Luckily, the Fourier transform is linear, so we can just add up and normalize displacements directly.

The size of each group of points leads to a time - frequency precision tradeoff, mediated by the same mathematics as Heisenberg's uncertainty principle.

Wavelets may be a more precise mathematical description of this intermediary time - frequency description.