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-rw-r--r--alc/effects/pshifter.cpp12
1 files changed, 6 insertions, 6 deletions
diff --git a/alc/effects/pshifter.cpp b/alc/effects/pshifter.cpp
index a91fd2fb..24b5979a 100644
--- a/alc/effects/pshifter.cpp
+++ b/alc/effects/pshifter.cpp
@@ -172,9 +172,9 @@ void PshifterState::process(const size_t samplesToDo, const al::span<const Float
complex_fft(mFftBuffer, -1.0);
/* Analyze the obtained data. Since the real FFT is symmetric, only
- * STFT_HALF_SIZE+1 samples are needed.
+ * STFT_HALF_SIZE samples are needed.
*/
- for(size_t k{0u};k < STFT_HALF_SIZE+1;k++)
+ for(size_t k{0u};k < STFT_HALF_SIZE;k++)
{
const double amplitude{std::abs(mFftBuffer[k])};
const double phase{std::arg(mFftBuffer[k])};
@@ -204,10 +204,10 @@ void PshifterState::process(const size_t samplesToDo, const al::span<const Float
* accumulating the amplitudes of overlapping frequency bins.
*/
std::fill(mSynthesisBuffer.begin(), mSynthesisBuffer.end(), FrequencyBin{});
- for(size_t k{0u};k < STFT_HALF_SIZE+1;k++)
+ for(size_t k{0u};k < STFT_HALF_SIZE;k++)
{
size_t j{(k*mPitchShiftI) >> FRACTIONBITS};
- if(j >= STFT_HALF_SIZE+1) break;
+ if(j >= STFT_HALF_SIZE) break;
mSynthesisBuffer[j].Amplitude += mAnalysisBuffer[k].Amplitude;
mSynthesisBuffer[j].Frequency = mAnalysisBuffer[k].Frequency * mPitchShift;
@@ -216,7 +216,7 @@ void PshifterState::process(const size_t samplesToDo, const al::span<const Float
/* Reconstruct the frequency-domain signal from the adjusted frequency
* bins.
*/
- for(size_t k{0u};k < STFT_HALF_SIZE+1;k++)
+ for(size_t k{0u};k < STFT_HALF_SIZE;k++)
{
/* Compute bin deviation from scaled freq */
const double tmp{mSynthesisBuffer[k].Frequency / freq_per_bin};
@@ -227,7 +227,7 @@ void PshifterState::process(const size_t samplesToDo, const al::span<const Float
mFftBuffer[k] = std::polar(mSynthesisBuffer[k].Amplitude, mSumPhase[k]);
}
/* Clear negative frequencies to recontruct the time-domain signal. */
- std::fill(mFftBuffer.begin()+STFT_HALF_SIZE+1, mFftBuffer.end(), complex_d{});
+ std::fill(mFftBuffer.begin()+STFT_HALF_SIZE, mFftBuffer.end(), complex_d{});
/* Apply an inverse FFT to get the time-domain siganl, and accumulate
* for the output with windowing.