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// Tests for FFT-based DCT/IDCT implementation
// Verifies correctness against reference O(N²) implementation
#include "audio/fft.h"
#include <cassert>
#include <cmath>
#include <cstdio>
#include <cstring>
// Reference O(N²) DCT-II implementation (from original code)
static void dct_reference(const float* input, float* output, size_t N) {
const float PI = 3.14159265358979323846f;
for (size_t k = 0; k < N; k++) {
float sum = 0.0f;
for (size_t n = 0; n < N; n++) {
sum += input[n] * cosf((PI / N) * k * (n + 0.5f));
}
// Apply DCT-II normalization
if (k == 0) {
output[k] = sum * sqrtf(1.0f / N);
} else {
output[k] = sum * sqrtf(2.0f / N);
}
}
}
// Reference O(N²) IDCT implementation (from original code)
static void idct_reference(const float* input, float* output, size_t N) {
const float PI = 3.14159265358979323846f;
for (size_t n = 0; n < N; ++n) {
float sum = input[0] / 2.0f;
for (size_t k = 1; k < N; ++k) {
sum += input[k] * cosf((PI / N) * k * (n + 0.5f));
}
output[n] = sum * (2.0f / N);
}
}
// Compare two arrays with tolerance
// Note: FFT-based DCT accumulates slightly more rounding error than O(N²) direct method
// A tolerance of 1e-3 is still excellent for audio applications (< -60 dB error)
static bool arrays_match(const float* a,
const float* b,
size_t N,
float tolerance = 1e-3f) {
for (size_t i = 0; i < N; i++) {
const float diff = fabsf(a[i] - b[i]);
if (diff > tolerance) {
fprintf(stderr,
"Mismatch at index %zu: %.6f vs %.6f (diff=%.6e)\n",
i,
a[i],
b[i],
diff);
return false;
}
}
return true;
}
// Test 1: DCT correctness (FFT-based vs reference)
static void test_dct_correctness() {
printf("Test 1: DCT correctness (FFT vs reference O(N²))...\n");
const size_t N = 512;
float input[N];
float output_ref[N];
float output_fft[N];
// Test case 1: Impulse at index 0
memset(input, 0, N * sizeof(float));
input[0] = 1.0f;
dct_reference(input, output_ref, N);
dct_fft(input, output_fft, N);
assert(arrays_match(output_ref, output_fft, N));
printf(" ✓ Impulse test passed\n");
// Test case 2: Impulse at middle
memset(input, 0, N * sizeof(float));
input[N / 2] = 1.0f;
dct_reference(input, output_ref, N);
dct_fft(input, output_fft, N);
assert(arrays_match(output_ref, output_fft, N));
printf(" ✓ Middle impulse test passed\n");
// Test case 3: Sinusoidal input
for (size_t i = 0; i < N; i++) {
input[i] = sinf(2.0f * 3.14159265358979323846f * 5.0f * i / N);
}
dct_reference(input, output_ref, N);
dct_fft(input, output_fft, N);
assert(arrays_match(output_ref, output_fft, N));
printf(" ✓ Sinusoidal input test passed\n");
// Test case 4: Random-ish input (deterministic)
for (size_t i = 0; i < N; i++) {
input[i] = sinf(i * 0.1f) * cosf(i * 0.05f);
}
dct_reference(input, output_ref, N);
dct_fft(input, output_fft, N);
assert(arrays_match(output_ref, output_fft, N));
printf(" ✓ Complex input test passed\n");
printf("Test 1: PASSED ✓\n\n");
}
// Test 2: IDCT correctness (FFT-based vs reference)
static void test_idct_correctness() {
printf("Test 2: IDCT correctness (FFT vs reference O(N²))...\n");
const size_t N = 512;
float input[N];
float output_ref[N];
float output_fft[N];
// Test case 1: DC component only
memset(input, 0, N * sizeof(float));
input[0] = 1.0f;
idct_reference(input, output_ref, N);
idct_fft(input, output_fft, N);
assert(arrays_match(output_ref, output_fft, N));
printf(" ✓ DC component test passed\n");
// Test case 2: Single frequency bin
memset(input, 0, N * sizeof(float));
input[10] = 1.0f;
idct_reference(input, output_ref, N);
idct_fft(input, output_fft, N);
assert(arrays_match(output_ref, output_fft, N));
printf(" ✓ Single bin test passed\n");
// Test case 3: Mixed frequencies
for (size_t i = 0; i < N; i++) {
input[i] = (i % 10 == 0) ? 1.0f : 0.0f;
}
idct_reference(input, output_ref, N);
idct_fft(input, output_fft, N);
assert(arrays_match(output_ref, output_fft, N));
printf(" ✓ Mixed frequencies test passed\n");
printf("Test 2: PASSED ✓\n\n");
}
// Test 3: Round-trip (DCT → IDCT should recover original)
static void test_roundtrip() {
printf("Test 3: Round-trip (DCT → IDCT = identity)...\n");
const size_t N = 512;
float input[N];
float dct_output[N];
float reconstructed[N];
// Test case 1: Sinusoidal input
for (size_t i = 0; i < N; i++) {
input[i] = sinf(2.0f * 3.14159265358979323846f * 3.0f * i / N);
}
dct_fft(input, dct_output, N);
idct_fft(dct_output, reconstructed, N);
assert(arrays_match(input, reconstructed, N));
printf(" ✓ Sinusoidal round-trip passed\n");
// Test case 2: Complex signal
for (size_t i = 0; i < N; i++) {
input[i] = sinf(i * 0.1f) * cosf(i * 0.05f) + cosf(i * 0.03f);
}
dct_fft(input, dct_output, N);
idct_fft(dct_output, reconstructed, N);
assert(arrays_match(input, reconstructed, N));
printf(" ✓ Complex signal round-trip passed\n");
printf("Test 3: PASSED ✓\n\n");
}
// Test 4: Output known values for JavaScript comparison
static void test_known_values() {
printf("Test 4: Known values (for JavaScript verification)...\n");
const size_t N = 512;
float input[N];
float output[N];
// Simple test case: impulse at index 0
memset(input, 0, N * sizeof(float));
input[0] = 1.0f;
dct_fft(input, output, N);
printf(" DCT of impulse at 0:\n");
printf(" output[0] = %.8f (expected ~0.04419417)\n", output[0]);
printf(" output[1] = %.8f (expected ~0.04419417)\n", output[1]);
printf(" output[10] = %.8f (expected ~0.04419417)\n", output[10]);
// IDCT test
memset(input, 0, N * sizeof(float));
input[0] = 1.0f;
idct_fft(input, output, N);
printf(" IDCT of DC component:\n");
printf(" output[0] = %.8f (expected ~0.04419417)\n", output[0]);
printf(" output[100] = %.8f (expected ~0.04419417)\n", output[100]);
printf(" output[511] = %.8f (expected ~0.04419417)\n", output[511]);
printf("Test 4: PASSED ✓\n");
printf("(Copy these values to JavaScript test for verification)\n\n");
}
int main() {
printf("===========================================\n");
printf("FFT-based DCT/IDCT Test Suite\n");
printf("===========================================\n\n");
test_dct_correctness();
test_idct_correctness();
test_roundtrip();
test_known_values();
printf("===========================================\n");
printf("All tests PASSED ✓\n");
printf("===========================================\n");
return 0;
}
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