//////////////////////////////////////////////////////////////////////////// // **** WAVPACK **** // // Hybrid Lossless Wavefile Compressor // // Copyright (c) 1998 - 2016 David Bryant. // // All Rights Reserved. // // Distributed under the BSD Software License (see license.txt) // //////////////////////////////////////////////////////////////////////////// This package contains all the source code required to build the WavPack library (libwavpack) and the command-line programs and it has been tested on many platforms. Assembly language optimizations are provided for x86 and x86-64 (AMD64) processors (encoding and decoding) and ARMv7 (decoding only). The x86 assembly code includes a runtime check for MMX capability, so it will work on legacy i386 processors. On Windows there are solution and project files for Visual Studio 2008 and additional sourcecode to build the CoolEdit/Audition plugin and the winamp plugin. The CoolEdit/Audition plugin provides a good example for using the library to both read and write WavPack files and the winamp plugin makes extensive use of APEv2 tag reading and writing. Both 32-bit and 64-bit platforms are provided. Visual Studio 2008 does not support projects with x64 assembly very well. I have provided a copy of the edited masm.rules file that works for me, but I can't provide support if your build does not work. Please make a copy of your masm.rules file first. On my system it lives here: C:\Program Files (x86)\Microsoft Visual Studio 9.0\VC\VCProjectDefaults To build everything on Linux, type: 1. ./configure [--disable-asm] [--enable-man] [--enable-rpath] [--enable-tests] 2. make 3. make install (optionally, to install into /usr/local/bin) If you are using the code directly from Git (rather than a distribution) then you will need to do a ./autogen.sh instead of the configure step. If assembly optimizations are available for your processor they will be automatically enabled, but if there is a problem with them then use the --disable-asm option to revert to pure C. For Clang-based build systems (Darwin, FreeBSD, etc.) Clang version 3.5 or higher is required. If you get a WARNING about unexpected libwavpack version when you run the command-line programs, you might try using --enable-rpath to hardcode the library location in the executables, or simply force static linking with --disable-shared. There is now a cli program to do a full suite of stress tests for libwavpack, and this is particularly useful for packagers to make sure that the assembly language optimizations are working correctly on various platforms. It is built with the configure option --enable-tests and requires Pthreads (it worked out-of-the-box on all the platforms I tried it on). There are lots of options, but the default test suite (consisting of 192 tests) is executed with "wvtest --default". On Windows a third-party Pthreads library is required, so I am not including this in the build for now. Notes: 1. There are three documentation files contained in the distribution: doc/wavpack_doc.html contains user-targeted documentation for the command-line programs doc/library_use.txt contains a detailed description of the API provided by WavPack library appropriate for read and writing WavPack files and manipulating APEv2 tags doc/file_format.txt contains a description of the WavPack file format, including details needed for parsing WavPack blocks and interpreting the block header and flags There is also a description of the WavPack algorithms in the forth edition of David Salomon's book "Data Compression: The Complete Reference". The section on WavPack can be found here: www.wavpack.com/WavPack.pdf 2. This code is designed to be easy to port to other platforms. It is endian- agnostic and usually uses callbacks for I/O, although there's a convenience function for reading files that accepts filename strings and automatically handles correction files (and on Windows there is now an option to select UTF-8 instead of ANSI). To maintain compatibility on various platforms, the following conventions are used: the "char" type must be 8-bits (signed or unsigned), a "short" must be 16-bits and the "int" and "long" types must be at least 32-bits. 3. The code's modules are organized in such a way that if major chunks of the functionality are not referenced (for example, creating WavPack files) then link-time dependency resolution should provide optimum binary sizes. However, some functionality could not be easily excluded in this way and so there are additional macros that may be used to further reduce the size of the binary. Note that these must be defined for all modules: VER4_ONLY to only handle WavPack files from version 4.0 onward (this is highly recommended for most applications because pre-4.0 WavPack files are very old) NO_SEEKING to not allow seeking to a specific sample index (for applications that always read entire files) NO_TAGS to not read specified fields from ID3v1 and APEv2 tags and not create or edit APEv2 tags 4. There are alternate versions of this library available specifically designed for "resource limited" CPUs or hardware encoding and decoding. There is the "tiny decoder" library which works with less than 32k of code and less than 4k of data and has assembly language optimizations for the ARM and Freescale ColdFire CPUs. The "tiny encoder" is also designed for embedded use and handles the pure lossless, lossy, and hybrid lossless modes. Neither of the "tiny" versions use any memory allocation functions nor do they require floating-point arithmetic support. 5. Questions or comments should be directed to david@wavpack.com