This is a simple set of C functions to read AES SOFA files, if they contain HRTFs stored according to the AES69-2015 standard [http://www.aes.org/publications/standards/search.cfm?docID=99].
On Ubuntu, to install the required components, enter
sudo apt install zlib1g-dev libcunit1-dev libcunit1-dev
Then, to compile enter following commands
cd build
cmake -DCMAKE_BUILD_TYPE=Debug ..
make all test
If you need an Debian package, call
cd build && cpack
To check for memory leaks and crazy pointers
export ASAN_SYMBOLIZER_PATH=/usr/bin/llvm-symbolizer
export ASAN_OPTIONS=symbolize=1
cmake -DCMAKE_BUILD_TYPE=Debug -DADDRESS_SANITIZE=ON -DVDEBUG=1 ..
make all test
Libmysofa has a few main function calls.
To read a SOFA file call
#include <mysofa.h>
int filter_length;
int err;
struct MYSOFA_EASY *hrtf = NULL;
hrtf = mysofa_open("file.sofa", 48000, &filter_length, &err);
if(hrtf==NULL)
return err;
This call will normalize your hrtf data upon opening. For non-normalized data, replace the call to mysofa_open by:
hrtf = mysofa_open_no_norm("file.sofa", 48000, &filter_length, &err);
Or for a complete control over neighbors search algorithm parameters:
bool norm = true; // bool, apply normalization upon import
float neighbor_angle_step = 5; // in degree, neighbor search angle step (common to azimuth and elevation)
float neighbor_radius_step = 0.01; // in meters, neighbor search radius step
hrtf = mysofa_open_advanced("file.sofa", 48000, &filter_length, &err, norm, neighbor_angle_step, neighbor_radius_step);
(The greater the neighbor_*_step, the faster the neighbors search. The algorithm will end up skipping true nearest neighbors if these values are set too high. To be define based on the will-be-imported sofa files grid step. Default mysofa_open method is usually fast enough for classical hrtf grids not to bother with the advanced one.)
Or, if you have loaded your HRTF file into memory already, call, for example
char buffer[9] = "TESTDATA";
int filter_length;
int err;
struct MYSOFA_EASY *hrtf = NULL;
hrtf = mysofa_open_data(buffer, 9, 48000, &filter_length, &err);
To free the HRTF structure, call:
mysofa_close(hrtf);
If you need HRTF filter for a given coordinate, just call
short leftIR[filter_length];
short rightIR[filter_length];
int leftDelay; // unit is samples
int rightDelay; // unit is samples
mysofa_getfilter_short(hrtf, x, y, z, leftIR, rightIR, &leftDelay, &rightDelay);
and then delay the audio signal by leftDelay and rightDelay samples and do a FIR filtering with leftIR and rightIR. Alternative, if you are using float values for the filtering, call
float leftIR[filter_length]; // [-1. till 1]
float rightIR[filter_length];
float leftDelay; // unit is sec.
float rightDelay; // unit is sec.
mysofa_getfilter_float(hrtf, x, y, z, leftIR, rightIR, &leftDelay, &rightDelay);
using mysofa_getfilter_float_nointerp
instead of mysofa_getfilter_float
(same arguments), you can bypass the linear interpolation applied by mysofa_getfilter_float
(weighted sum of nearest neighbors filters coefficients), and get the exact filter stored in the sofa file nearest to the [x,y,z] position requested.
If you have spherical coordinates but you need Cartesian coordinates, call
void mysofa_s2c(float values[3])
with phi (azimuth in degree, measured counterclockwise from the X axis), theta (elevation in degree, measured up from the X-Y plane), and r (distance between listener and source) as parameters in the float array and x,y,z as response in the same array. Similar, call
void mysofa_c2s(float values[3])
The coordinate system is defined in the SOFA specification and is the same as in the SOFA file. Typically, the X axis vector (1 0 0) is the listening direction. The Y axis (0 1 0) is the left side of the listener and Z (0 0 1) is upwards.
Sometimes, you want to use multiple SOFA filters or if you have to open a SOFA file multiple times, you may use
hrtf1 = mysofa_open_cached("file.sofa", 48000, &filter_length, &err);
hrtf2 = mysofa_open_cached("file.sofa", 48000, &filter_length, &err);
hrtf3 = mysofa_open_cached("file.sofa", 8000, &filter_length, &err);
hrtf3 = mysofa_open_cached("file2.sofa", 8000, &filter_length, &err);
mysofa_close_cached(hrtf1);
mysofa_close_cached(hrtf2);
mysofa_close_cached(hrtf3);
mysofa_close_cached(hrtf4);
...
mysofa_cache_release_all();
Then, all HRTFs having the same filename and sampling rate are stored only once in memory. If your program is using several threads, you must use appropriate synchronisation mechanisms so only a single thread can access the mysofa_open_cached and mysofa_close_cached functions at a given time.
Libmysofa compiles for Linux operating systems, OSX and Windows. By default, each commit is compiled with Travis CI under Ubuntu 14.04 and OSX 7.3 and with AppVeyor for Windows Visual Studio 2015 on a x64 system. In addition, FFmpeg is compiling libmysofa with MinGW under Windows using their own build system.
- Christian Hoene and Piotr Majdak, "HDF5 under the SOFA – A 3D audio case in HDF5 on embedded and mobile devices", HDF Blog, https://www.hdfgroup.org/2017/04/hdf5-under-the-sofa-hdf5-on-embedded-and-mobile-devices/, April 26, 2017.
- Christian Hoene, Isabel C. Patiño Mejía, Alexandru Cacerovschi, "MySofa: Design Your Personal HRTF", Audio Engineering Society Convention Paper 9764, Presented at the 142nd Convention, May 2017, Berlin, Germany, http://www.aes.org/e-lib/browse.cfm?elib=18640
The SOFA files are from https://www.sofaconventions.org/, Piotr Majdak piotr@majdak.com. The K-D tree algorithm is by John Tsiombikas nuclear@member.fsf.org. The resampler is by Jean-Marc Valin. The remaining source code is by Christian Hoene christian.hoene@symonics.com, Symonics GmbH, and available under BSD-3-Clause license. This work has been funded by German Federal Ministry of Education and Research, funding code 01IS14027A.