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-rw-r--r--utils/makehrtf.cpp127
1 files changed, 93 insertions, 34 deletions
diff --git a/utils/makehrtf.cpp b/utils/makehrtf.cpp
index b0da4620..a5fb90f7 100644
--- a/utils/makehrtf.cpp
+++ b/utils/makehrtf.cpp
@@ -80,9 +80,11 @@
#include "getopt.h"
#endif
-#include <cmath>
+#include <atomic>
#include <limits>
#include <vector>
+#include <chrono>
+#include <thread>
#include <complex>
#include <numeric>
#include <algorithm>
@@ -2261,52 +2263,109 @@ static void DiffuseFieldEqualize(const uint channels, const uint m, const double
}
}
-// Perform minimum-phase reconstruction using the magnitude responses of the
-// HRIR set.
+/* Perform minimum-phase reconstruction using the magnitude responses of the
+ * HRIR set. Work is delegated to this struct, which runs asynchronously on one
+ * or more threads (sharing the same reconstructor object).
+ */
+struct HrirReconstructor {
+ std::vector<double*> mIrs;
+ std::atomic<size_t> mCurrent;
+ std::atomic<size_t> mDone;
+ size_t mFftSize;
+ size_t mIrPoints;
+
+ void Worker()
+ {
+ auto h = std::vector<complex_d>(mFftSize);
+
+ while(1)
+ {
+ /* Load the current index to process. */
+ size_t idx{mCurrent.load()};
+ do {
+ /* If the index is at the end, we're done. */
+ if(idx >= mIrs.size())
+ return;
+ /* Otherwise, increment the current index atomically so other
+ * threads know to go to the next one. If this call fails, the
+ * current index was just changed by another thread and the new
+ * value is loaded into idx, which we'll recheck.
+ */
+ } while(!mCurrent.compare_exchange_weak(idx, idx+1, std::memory_order_relaxed));
+
+ /* Now do the reconstruction, and apply the inverse FFT to get the
+ * time-domain response.
+ */
+ MinimumPhase(mFftSize, mIrs[idx], h.data());
+ FftInverse(mFftSize, h.data());
+ for(size_t i{0u};i < mIrPoints;++i)
+ mIrs[idx][i] = h[i].real();
+
+ /* Increment the number of IRs done. */
+ mDone.fetch_add(1);
+ }
+ }
+};
+
static void ReconstructHrirs(const HrirDataT *hData)
{
- uint channels = (hData->mChannelType == CT_STEREO) ? 2 : 1;
- uint n = hData->mFftSize;
- uint ti, fi, ei, ai, i;
- std::vector<complex_d> h(n);
- uint total, count, pcdone, lastpc;
+ const uint channels{(hData->mChannelType == CT_STEREO) ? 2u : 1u};
- total = hData->mIrCount;
- for(fi = 0;fi < hData->mFdCount;fi++)
+ /* Count the number of IRs to process (excluding elevations that will be
+ * synthesized later).
+ */
+ size_t total{hData->mIrCount};
+ for(uint fi{0u};fi < hData->mFdCount;fi++)
{
- for(ei = 0;ei < hData->mFds[fi].mEvStart;ei++)
+ for(uint ei{0u};ei < hData->mFds[fi].mEvStart;ei++)
total -= hData->mFds[fi].mEvs[ei].mAzCount;
}
total *= channels;
- count = pcdone = lastpc = 0;
- printf("%3d%% done.", pcdone);
- fflush(stdout);
- for(fi = 0;fi < hData->mFdCount;fi++)
+
+ /* Set up the reconstructor with the needed size info and pointers to the
+ * IRs to process.
+ */
+ HrirReconstructor reconstructor;
+ reconstructor.mIrs.reserve(total);
+ reconstructor.mCurrent.store(0, std::memory_order_relaxed);
+ reconstructor.mDone.store(0, std::memory_order_relaxed);
+ reconstructor.mFftSize = hData->mFftSize;
+ reconstructor.mIrPoints = hData->mIrPoints;
+ for(uint fi{0u};fi < hData->mFdCount;fi++)
{
- for(ei = hData->mFds[fi].mEvStart;ei < hData->mFds[fi].mEvCount;ei++)
+ const HrirFdT &field = hData->mFds[fi];
+ for(uint ei{field.mEvStart};ei < field.mEvCount;ei++)
{
- for(ai = 0;ai < hData->mFds[fi].mEvs[ei].mAzCount;ai++)
+ const HrirEvT &elev = field.mEvs[ei];
+ for(uint ai{0u};ai < elev.mAzCount;ai++)
{
- HrirAzT *azd = &hData->mFds[fi].mEvs[ei].mAzs[ai];
-
- for(ti = 0;ti < channels;ti++)
- {
- MinimumPhase(n, azd->mIrs[ti], h.data());
- FftInverse(n, h.data());
- for(i = 0;i < hData->mIrPoints;i++)
- azd->mIrs[ti][i] = h[i].real();
- pcdone = ++count * 100 / total;
- if(pcdone != lastpc)
- {
- lastpc = pcdone;
- printf("\r%3d%% done.", pcdone);
- fflush(stdout);
- }
- }
+ const HrirAzT &azd = elev.mAzs[ai];
+ for(uint ti{0u};ti < channels;ti++)
+ reconstructor.mIrs.push_back(azd.mIrs[ti]);
}
}
}
- printf("\n");
+
+ /* Launch two threads to work on reconstruction. */
+ std::thread thrd1{std::mem_fn(&HrirReconstructor::Worker), &reconstructor};
+ std::thread thrd2{std::mem_fn(&HrirReconstructor::Worker), &reconstructor};
+
+ /* Keep track of the number of IRs done, periodically reporting it. */
+ size_t count;
+ while((count=reconstructor.mDone.load()) != total)
+ {
+ size_t pcdone{count * 100 / total};
+
+ printf("\r%3zu%% done (%zu of %zu)", pcdone, count, total);
+ fflush(stdout);
+
+ std::this_thread::sleep_for(std::chrono::milliseconds{50});
+ }
+ size_t pcdone{count * 100 / total};
+ printf("\r%3zu%% done (%zu of %zu)\n", pcdone, count, total);
+
+ if(thrd2.joinable()) thrd2.join();
+ if(thrd1.joinable()) thrd1.join();
}
// Resamples the HRIRs for use at the given sampling rate.