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/*************************************************************************** |
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* * |
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* libgig - C++ cross-platform Gigasampler format file loader library * |
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* * |
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* Copyright (C) 2003 by Christian Schoenebeck * |
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* <cuse@users.sourceforge.net> * |
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* * |
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* This library is free software; you can redistribute it and/or modify * |
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* it under the terms of the GNU General Public License as published by * |
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* the Free Software Foundation; either version 2 of the License, or * |
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* (at your option) any later version. * |
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* * |
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* This library is distributed in the hope that it will be useful, * |
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* but WITHOUT ANY WARRANTY; without even the implied warranty of * |
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* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * |
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* GNU General Public License for more details. * |
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* * |
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* You should have received a copy of the GNU General Public License * |
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* along with this library; if not, write to the Free Software * |
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* Foundation, Inc., 59 Temple Place, Suite 330, Boston, * |
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* MA 02111-1307 USA * |
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***************************************************************************/ |
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|
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#include "gig.h" |
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|
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namespace gig { |
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|
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// *************** Sample *************** |
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// * |
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|
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unsigned int Sample::Instances = 0; |
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void* Sample::pDecompressionBuffer = NULL; |
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unsigned long Sample::DecompressionBufferSize = 0; |
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|
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Sample::Sample(File* pFile, RIFF::List* waveList, unsigned long WavePoolOffset) : DLS::Sample((DLS::File*) pFile, waveList, WavePoolOffset) { |
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Instances++; |
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|
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RIFF::Chunk* _3gix = waveList->GetSubChunk(CHUNK_ID_3GIX); |
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if (!_3gix) throw gig::Exception("Mandatory chunks in <wave> list chunk not found."); |
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SampleGroup = _3gix->ReadInt16(); |
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|
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RIFF::Chunk* smpl = waveList->GetSubChunk(CHUNK_ID_SMPL); |
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if (!smpl) throw gig::Exception("Mandatory chunks in <wave> list chunk not found."); |
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Manufacturer = smpl->ReadInt32(); |
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Product = smpl->ReadInt32(); |
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SamplePeriod = smpl->ReadInt32(); |
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MIDIUnityNote = smpl->ReadInt32(); |
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FineTune = smpl->ReadInt32(); |
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smpl->Read(&SMPTEFormat, 1, 4); |
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SMPTEOffset = smpl->ReadInt32(); |
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Loops = smpl->ReadInt32(); |
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uint32_t manufByt = smpl->ReadInt32(); |
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LoopID = smpl->ReadInt32(); |
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smpl->Read(&LoopType, 1, 4); |
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LoopStart = smpl->ReadInt32(); |
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LoopEnd = smpl->ReadInt32(); |
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LoopFraction = smpl->ReadInt32(); |
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LoopPlayCount = smpl->ReadInt32(); |
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|
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FrameTable = NULL; |
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SamplePos = 0; |
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RAMCache.Size = 0; |
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RAMCache.pStart = NULL; |
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RAMCache.NullExtensionSize = 0; |
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|
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Compressed = (waveList->GetSubChunk(CHUNK_ID_EWAV)); |
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if (Compressed) { |
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ScanCompressedSample(); |
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if (!pDecompressionBuffer) { |
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pDecompressionBuffer = new int8_t[INITIAL_SAMPLE_BUFFER_SIZE]; |
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DecompressionBufferSize = INITIAL_SAMPLE_BUFFER_SIZE; |
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} |
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} |
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FrameOffset = 0; // just for streaming compressed samples |
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|
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LoopStart /= FrameSize; // convert to sample points |
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LoopEnd /= FrameSize; // convert to sample points |
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LoopSize = LoopEnd - LoopStart; |
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} |
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|
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/// Scans compressed samples for mandatory informations (e.g. actual number of total sample points). |
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void Sample::ScanCompressedSample() { |
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//TODO: we have to add some more scans here (e.g. determine compression rate) |
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this->SamplesTotal = 0; |
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std::list<unsigned long> frameOffsets; |
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|
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// Scanning |
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pCkData->SetPos(0); |
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while (pCkData->GetState() == RIFF::stream_ready) { |
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frameOffsets.push_back(pCkData->GetPos()); |
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int16_t compressionmode = pCkData->ReadInt16(); |
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this->SamplesTotal += 2048; |
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switch (compressionmode) { |
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case 1: // left channel compressed |
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case 256: // right channel compressed |
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pCkData->SetPos(6148, RIFF::stream_curpos); |
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break; |
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case 257: // both channels compressed |
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pCkData->SetPos(4104, RIFF::stream_curpos); |
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break; |
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default: // both channels uncompressed |
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pCkData->SetPos(8192, RIFF::stream_curpos); |
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} |
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} |
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pCkData->SetPos(0); |
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|
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//FIXME: only seen compressed samples with 16 bit stereo so far |
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this->FrameSize = 4; |
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this->BitDepth = 16; |
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|
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// Build the frames table (which is used for fast resolving of a frame's chunk offset) |
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if (FrameTable) delete[] FrameTable; |
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FrameTable = new unsigned long[frameOffsets.size()]; |
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std::list<unsigned long>::iterator end = frameOffsets.end(); |
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std::list<unsigned long>::iterator iter = frameOffsets.begin(); |
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for (int i = 0; iter != end; i++, iter++) { |
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FrameTable[i] = *iter; |
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} |
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} |
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|
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/** |
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* Loads (and uncompresses if needed) the whole sample wave into RAM. Use |
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* ReleaseSampleData() to free the memory if you don't need the cached |
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* sample data anymore. |
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* |
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* @returns buffer_t structure with start address and size of the buffer |
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* in bytes |
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* @see ReleaseSampleData(), Read(), SetPos() |
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*/ |
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buffer_t Sample::LoadSampleData() { |
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return LoadSampleDataWithNullSamplesExtension(this->SamplesTotal, 0); // 0 amount of NullSamples |
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} |
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|
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/** |
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* Reads (uncompresses if needed) and caches the first \a SampleCount |
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* numbers of SamplePoints in RAM. Use ReleaseSampleData() to free the |
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* memory space if you don't need the cached samples anymore. There is no |
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* guarantee that exactly \a SampleCount samples will be cached; this is |
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* not an error. The size will be eventually truncated e.g. to the |
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* beginning of a frame of a compressed sample. This is done for |
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* efficiency reasons while streaming the wave by your sampler engine |
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* later. Read the <i>Size</i> member of the <i>buffer_t</i> structure |
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* that will be returned to determine the actual cached samples, but note |
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* that the size is given in bytes! You get the number of actually cached |
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* samples by dividing it by the frame size of the sample: |
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* |
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* buffer_t buf = pSample->LoadSampleData(acquired_samples); |
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* long cachedsamples = buf.Size / pSample->FrameSize; |
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* |
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* @param SampleCount - number of sample points to load into RAM |
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* @returns buffer_t structure with start address and size of |
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* the cached sample data in bytes |
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* @see ReleaseSampleData(), Read(), SetPos() |
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*/ |
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buffer_t Sample::LoadSampleData(unsigned long SampleCount) { |
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return LoadSampleDataWithNullSamplesExtension(SampleCount, 0); // 0 amount of NullSamples |
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} |
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|
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/** |
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* Loads (and uncompresses if needed) the whole sample wave into RAM. Use |
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* ReleaseSampleData() to free the memory if you don't need the cached |
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* sample data anymore. |
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* The method will add \a NullSamplesCount silence samples past the |
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* official buffer end (this won't affect the 'Size' member of the |
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* buffer_t structure, that means 'Size' always reflects the size of the |
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* actual sample data, the buffer might be bigger though). Silence |
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* samples past the official buffer are needed for differential |
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* algorithms that always have to take subsequent samples into account |
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* (resampling/interpolation would be an important example) and avoids |
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* memory access faults in such cases. |
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* |
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* @param NullSamplesCount - number of silence samples the buffer should |
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* be extended past it's data end |
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* @returns buffer_t structure with start address and |
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* size of the buffer in bytes |
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* @see ReleaseSampleData(), Read(), SetPos() |
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*/ |
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buffer_t Sample::LoadSampleDataWithNullSamplesExtension(uint NullSamplesCount) { |
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return LoadSampleDataWithNullSamplesExtension(this->SamplesTotal, NullSamplesCount); |
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} |
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|
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/** |
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* Reads (uncompresses if needed) and caches the first \a SampleCount |
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* numbers of SamplePoints in RAM. Use ReleaseSampleData() to free the |
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* memory space if you don't need the cached samples anymore. There is no |
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* guarantee that exactly \a SampleCount samples will be cached; this is |
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* not an error. The size will be eventually truncated e.g. to the |
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* beginning of a frame of a compressed sample. This is done for |
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* efficiency reasons while streaming the wave by your sampler engine |
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* later. Read the <i>Size</i> member of the <i>buffer_t</i> structure |
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* that will be returned to determine the actual cached samples, but note |
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* that the size is given in bytes! You get the number of actually cached |
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* samples by dividing it by the frame size of the sample: |
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* |
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* buffer_t buf = pSample->LoadSampleDataWithNullSamplesExtension(acquired_samples, null_samples); |
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* long cachedsamples = buf.Size / pSample->FrameSize; |
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* |
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* The method will add \a NullSamplesCount silence samples past the |
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* official buffer end (this won't affect the 'Size' member of the |
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* buffer_t structure, that means 'Size' always reflects the size of the |
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* actual sample data, the buffer might be bigger though). Silence |
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* samples past the official buffer are needed for differential |
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* algorithms that always have to take subsequent samples into account |
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* (resampling/interpolation would be an important example) and avoids |
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* memory access faults in such cases. |
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* |
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* @param SampleCount - number of sample points to load into RAM |
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* @param NullSamplesCount - number of silence samples the buffer should |
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* be extended past it's data end |
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* @returns buffer_t structure with start address and |
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* size of the cached sample data in bytes |
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* @see ReleaseSampleData(), Read(), SetPos() |
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*/ |
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buffer_t Sample::LoadSampleDataWithNullSamplesExtension(unsigned long SampleCount, uint NullSamplesCount) { |
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if (SampleCount > this->SamplesTotal) SampleCount = this->SamplesTotal; |
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if (RAMCache.pStart) delete[] (int8_t*) RAMCache.pStart; |
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unsigned long allocationsize = (SampleCount + NullSamplesCount) * this->FrameSize; |
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RAMCache.pStart = new int8_t[allocationsize]; |
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RAMCache.Size = Read(RAMCache.pStart, SampleCount) * this->FrameSize; |
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RAMCache.NullExtensionSize = allocationsize - RAMCache.Size; |
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// fill the remaining buffer space with silence samples |
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memset((int8_t*)RAMCache.pStart + RAMCache.Size, 0, RAMCache.NullExtensionSize); |
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return GetCache(); |
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} |
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|
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/** |
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* Returns current cached sample points. A buffer_t structure will be |
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* returned which contains address pointer to the begin of the cache and |
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* the size of the cached sample data in bytes. Use |
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* <i>LoadSampleData()</i> to cache a specific amount of sample points in |
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* RAM. |
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* |
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* @returns buffer_t structure with current cached sample points |
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* @see LoadSampleData(); |
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*/ |
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buffer_t Sample::GetCache() { |
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// return a copy of the buffer_t structure |
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buffer_t result; |
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result.Size = this->RAMCache.Size; |
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result.pStart = this->RAMCache.pStart; |
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result.NullExtensionSize = this->RAMCache.NullExtensionSize; |
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return result; |
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} |
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|
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/** |
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* Frees the cached sample from RAM if loaded with |
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* <i>LoadSampleData()</i> previously. |
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* |
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* @see LoadSampleData(); |
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*/ |
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void Sample::ReleaseSampleData() { |
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if (RAMCache.pStart) delete[] (int8_t*) RAMCache.pStart; |
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RAMCache.pStart = NULL; |
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RAMCache.Size = 0; |
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} |
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|
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/** |
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* Sets the position within the sample (in sample points, not in |
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* bytes). Use this method and <i>Read()</i> if you don't want to load |
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* the sample into RAM, thus for disk streaming. |
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* |
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* Although the original Gigasampler engine doesn't allow positioning |
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* within compressed samples, I decided to implement it. Even though |
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* the Gigasampler format doesn't allow to define loops for compressed |
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* samples at the moment, positioning within compressed samples might be |
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* interesting for some sampler engines though. The only drawback about |
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* my decision is that it takes longer to load compressed gig Files on |
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* startup, because it's neccessary to scan the samples for some |
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* mandatory informations. But I think as it doesn't affect the runtime |
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* efficiency, nobody will have a problem with that. |
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* |
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* @param SampleCount number of sample points to jump |
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* @param Whence optional: to which relation \a SampleCount refers |
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* to, if omited <i>RIFF::stream_start</i> is assumed |
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* @returns the new sample position |
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* @see Read() |
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*/ |
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unsigned long Sample::SetPos(unsigned long SampleCount, RIFF::stream_whence_t Whence) { |
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if (Compressed) { |
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switch (Whence) { |
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case RIFF::stream_curpos: |
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this->SamplePos += SampleCount; |
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break; |
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case RIFF::stream_end: |
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this->SamplePos = this->SamplesTotal - 1 - SampleCount; |
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break; |
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case RIFF::stream_backward: |
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this->SamplePos -= SampleCount; |
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break; |
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case RIFF::stream_start: default: |
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this->SamplePos = SampleCount; |
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break; |
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} |
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if (this->SamplePos > this->SamplesTotal) this->SamplePos = this->SamplesTotal; |
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|
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unsigned long frame = this->SamplePos / 2048; // to which frame to jump |
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this->FrameOffset = this->SamplePos % 2048; // offset (in sample points) within that frame |
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pCkData->SetPos(FrameTable[frame]); // set chunk pointer to the start of sought frame |
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return this->SamplePos; |
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} |
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else { // not compressed |
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unsigned long orderedBytes = SampleCount * this->FrameSize; |
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unsigned long result = pCkData->SetPos(orderedBytes, Whence); |
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return (result == orderedBytes) ? SampleCount |
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: result / this->FrameSize; |
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} |
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} |
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|
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/** |
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* Returns the current position in the sample (in sample points). |
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*/ |
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unsigned long Sample::GetPos() { |
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if (Compressed) return SamplePos; |
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else return pCkData->GetPos() / FrameSize; |
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} |
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|
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/** |
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* Reads \a SampleCount number of sample points from the current |
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* position into the buffer pointed by \a pBuffer and increments the |
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* position within the sample. The sample wave stream will be |
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* decompressed on the fly if using a compressed sample. Use this method |
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* and <i>SetPos()</i> if you don't want to load the sample into RAM, |
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* thus for disk streaming. |
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* |
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* @param pBuffer destination buffer |
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* @param SampleCount number of sample points to read |
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* @returns number of successfully read sample points |
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* @see SetPos() |
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*/ |
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unsigned long Sample::Read(void* pBuffer, unsigned long SampleCount) { |
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if (SampleCount == 0) return 0; |
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if (!Compressed) return pCkData->Read(pBuffer, SampleCount, FrameSize); //FIXME: channel inversion due to endian correction? |
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else { //FIXME: no support for mono compressed samples yet, are there any? |
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if (this->SamplePos >= this->SamplesTotal) return 0; |
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//TODO: efficiency: we simply assume here that all frames are compressed, maybe we should test for an average compression rate |
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// best case needed buffer size (all frames compressed) |
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unsigned long assumedsize = (SampleCount << 1) + // *2 (16 Bit, stereo, but assume all frames compressed) |
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(SampleCount >> 10) + // 10 bytes header per 2048 sample points |
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8194, // at least one worst case sample frame |
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remainingbytes = 0, // remaining bytes in the local buffer |
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remainingsamples = SampleCount, |
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copysamples; |
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int currentframeoffset = this->FrameOffset; // offset in current sample frame since last Read() |
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this->FrameOffset = 0; |
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|
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if (assumedsize > this->DecompressionBufferSize) { |
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// local buffer reallocation - hope this won't happen |
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if (this->pDecompressionBuffer) delete[] (int8_t*) this->pDecompressionBuffer; |
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this->pDecompressionBuffer = new int8_t[assumedsize << 1]; // double of current needed size |
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this->DecompressionBufferSize = assumedsize; |
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} |
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|
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int16_t compressionmode, left, dleft, right, dright; |
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int8_t* pSrc = (int8_t*) this->pDecompressionBuffer; |
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int16_t* pDst = (int16_t*) pBuffer; |
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remainingbytes = pCkData->Read(pSrc, assumedsize, 1); |
357 |
|
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while (remainingsamples) { |
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|
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// reload from disk to local buffer if needed |
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if (remainingbytes < 8194) { |
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if (pCkData->GetState() != RIFF::stream_ready) { |
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this->SamplePos = this->SamplesTotal; |
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return (SampleCount - remainingsamples); |
365 |
} |
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assumedsize = remainingsamples; |
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assumedsize = (assumedsize << 1) + // *2 (16 Bit, stereo, but assume all frames compressed) |
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(assumedsize >> 10) + // 10 bytes header per 2048 sample points |
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8194; // at least one worst case sample frame |
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pCkData->SetPos(remainingbytes, RIFF::stream_backward); |
371 |
if (pCkData->RemainingBytes() < assumedsize) assumedsize = pCkData->RemainingBytes(); |
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remainingbytes = pCkData->Read(this->pDecompressionBuffer, assumedsize, 1); |
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pSrc = (int8_t*) this->pDecompressionBuffer; |
374 |
} |
375 |
|
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// determine how many samples in this frame to skip and read |
377 |
if (remainingsamples >= 2048) { |
378 |
copysamples = 2048 - currentframeoffset; |
379 |
remainingsamples -= copysamples; |
380 |
} |
381 |
else { |
382 |
copysamples = remainingsamples; |
383 |
if (currentframeoffset + copysamples > 2048) { |
384 |
copysamples = 2048 - currentframeoffset; |
385 |
remainingsamples -= copysamples; |
386 |
} |
387 |
else { |
388 |
pCkData->SetPos(remainingbytes, RIFF::stream_backward); |
389 |
remainingsamples = 0; |
390 |
this->FrameOffset = currentframeoffset + copysamples; |
391 |
} |
392 |
} |
393 |
|
394 |
// decompress and copy current frame from local buffer to destination buffer |
395 |
compressionmode = *(int16_t*)pSrc; pSrc+=2; |
396 |
switch (compressionmode) { |
397 |
case 1: // left channel compressed |
398 |
remainingbytes -= 6150; // (left 8 bit, right 16 bit, +6 byte header) |
399 |
if (!remainingsamples && copysamples == 2048) |
400 |
pCkData->SetPos(remainingbytes, RIFF::stream_backward); |
401 |
|
402 |
left = *(int16_t*)pSrc; pSrc+=2; |
403 |
dleft = *(int16_t*)pSrc; pSrc+=2; |
404 |
while (currentframeoffset) { |
405 |
dleft -= *pSrc; |
406 |
left -= dleft; |
407 |
pSrc+=3; // 8 bit left channel, skip uncompressed right channel (16 bit) |
408 |
currentframeoffset--; |
409 |
} |
410 |
while (copysamples) { |
411 |
dleft -= *pSrc; pSrc++; |
412 |
left -= dleft; |
413 |
*pDst = left; pDst++; |
414 |
*pDst = *(int16_t*)pSrc; pDst++; pSrc+=2; |
415 |
copysamples--; |
416 |
} |
417 |
break; |
418 |
case 256: // right channel compressed |
419 |
remainingbytes -= 6150; // (left 16 bit, right 8 bit, +6 byte header) |
420 |
if (!remainingsamples && copysamples == 2048) |
421 |
pCkData->SetPos(remainingbytes, RIFF::stream_backward); |
422 |
|
423 |
right = *(int16_t*)pSrc; pSrc+=2; |
424 |
dright = *(int16_t*)pSrc; pSrc+=2; |
425 |
if (currentframeoffset) { |
426 |
pSrc+=2; // skip uncompressed left channel, now we can increment by 3 |
427 |
while (currentframeoffset) { |
428 |
dright -= *pSrc; |
429 |
right -= dright; |
430 |
pSrc+=3; // 8 bit right channel, skip uncompressed left channel (16 bit) |
431 |
currentframeoffset--; |
432 |
} |
433 |
pSrc-=2; // back aligned to left channel |
434 |
} |
435 |
while (copysamples) { |
436 |
*pDst = *(int16_t*)pSrc; pDst++; pSrc+=2; |
437 |
dright -= *pSrc; pSrc++; |
438 |
right -= dright; |
439 |
*pDst = right; pDst++; |
440 |
copysamples--; |
441 |
} |
442 |
break; |
443 |
case 257: // both channels compressed |
444 |
remainingbytes -= 4106; // (left 8 bit, right 8 bit, +10 byte header) |
445 |
if (!remainingsamples && copysamples == 2048) |
446 |
pCkData->SetPos(remainingbytes, RIFF::stream_backward); |
447 |
|
448 |
left = *(int16_t*)pSrc; pSrc+=2; |
449 |
dleft = *(int16_t*)pSrc; pSrc+=2; |
450 |
right = *(int16_t*)pSrc; pSrc+=2; |
451 |
dright = *(int16_t*)pSrc; pSrc+=2; |
452 |
while (currentframeoffset) { |
453 |
dleft -= *pSrc; pSrc++; |
454 |
left -= dleft; |
455 |
dright -= *pSrc; pSrc++; |
456 |
right -= dright; |
457 |
currentframeoffset--; |
458 |
} |
459 |
while (copysamples) { |
460 |
dleft -= *pSrc; pSrc++; |
461 |
left -= dleft; |
462 |
dright -= *pSrc; pSrc++; |
463 |
right -= dright; |
464 |
*pDst = left; pDst++; |
465 |
*pDst = right; pDst++; |
466 |
copysamples--; |
467 |
} |
468 |
break; |
469 |
default: // both channels uncompressed |
470 |
remainingbytes -= 8194; // (left 16 bit, right 16 bit, +2 byte header) |
471 |
if (!remainingsamples && copysamples == 2048) |
472 |
pCkData->SetPos(remainingbytes, RIFF::stream_backward); |
473 |
|
474 |
pSrc += currentframeoffset << 2; |
475 |
currentframeoffset = 0; |
476 |
memcpy(pDst, pSrc, copysamples << 2); |
477 |
pDst += copysamples << 1; |
478 |
pSrc += copysamples << 2; |
479 |
break; |
480 |
} |
481 |
} |
482 |
this->SamplePos += (SampleCount - remainingsamples); |
483 |
if (this->SamplePos > this->SamplesTotal) this->SamplePos = this->SamplesTotal; |
484 |
return (SampleCount - remainingsamples); |
485 |
} |
486 |
} |
487 |
|
488 |
Sample::~Sample() { |
489 |
Instances--; |
490 |
if (!Instances && pDecompressionBuffer) delete[] (int8_t*) pDecompressionBuffer; |
491 |
if (FrameTable) delete[] FrameTable; |
492 |
if (RAMCache.pStart) delete[] (int8_t*) RAMCache.pStart; |
493 |
} |
494 |
|
495 |
|
496 |
|
497 |
// *************** DimensionRegion *************** |
498 |
// * |
499 |
|
500 |
uint DimensionRegion::Instances = 0; |
501 |
DimensionRegion::VelocityTableMap* DimensionRegion::pVelocityTables = NULL; |
502 |
|
503 |
DimensionRegion::DimensionRegion(RIFF::List* _3ewl) : DLS::Sampler(_3ewl) { |
504 |
Instances++; |
505 |
|
506 |
memcpy(&Crossfade, &SamplerOptions, 4); |
507 |
if (!pVelocityTables) pVelocityTables = new VelocityTableMap; |
508 |
|
509 |
RIFF::Chunk* _3ewa = _3ewl->GetSubChunk(CHUNK_ID_3EWA); |
510 |
_3ewa->ReadInt32(); // unknown, allways 0x0000008C ? |
511 |
LFO3Frequency = (double) GIG_EXP_DECODE(_3ewa->ReadInt32()); |
512 |
EG3Attack = (double) GIG_EXP_DECODE(_3ewa->ReadInt32()); |
513 |
_3ewa->ReadInt16(); // unknown |
514 |
LFO1InternalDepth = _3ewa->ReadUint16(); |
515 |
_3ewa->ReadInt16(); // unknown |
516 |
LFO3InternalDepth = _3ewa->ReadInt16(); |
517 |
_3ewa->ReadInt16(); // unknown |
518 |
LFO1ControlDepth = _3ewa->ReadUint16(); |
519 |
_3ewa->ReadInt16(); // unknown |
520 |
LFO3ControlDepth = _3ewa->ReadInt16(); |
521 |
EG1Attack = (double) GIG_EXP_DECODE(_3ewa->ReadInt32()); |
522 |
EG1Decay1 = (double) GIG_EXP_DECODE(_3ewa->ReadInt32()); |
523 |
_3ewa->ReadInt16(); // unknown |
524 |
EG1Sustain = _3ewa->ReadUint16(); |
525 |
EG1Release = (double) GIG_EXP_DECODE(_3ewa->ReadInt32()); |
526 |
EG1Controller = static_cast<eg1_ctrl_t>(_3ewa->ReadUint8()); |
527 |
uint8_t eg1ctrloptions = _3ewa->ReadUint8(); |
528 |
EG1ControllerInvert = eg1ctrloptions & 0x01; |
529 |
EG1ControllerAttackInfluence = GIG_EG_CTR_ATTACK_INFLUENCE_EXTRACT(eg1ctrloptions); |
530 |
EG1ControllerDecayInfluence = GIG_EG_CTR_DECAY_INFLUENCE_EXTRACT(eg1ctrloptions); |
531 |
EG1ControllerReleaseInfluence = GIG_EG_CTR_RELEASE_INFLUENCE_EXTRACT(eg1ctrloptions); |
532 |
EG2Controller = static_cast<eg2_ctrl_t>(_3ewa->ReadUint8()); |
533 |
uint8_t eg2ctrloptions = _3ewa->ReadUint8(); |
534 |
EG2ControllerInvert = eg2ctrloptions & 0x01; |
535 |
EG2ControllerAttackInfluence = GIG_EG_CTR_ATTACK_INFLUENCE_EXTRACT(eg2ctrloptions); |
536 |
EG2ControllerDecayInfluence = GIG_EG_CTR_DECAY_INFLUENCE_EXTRACT(eg2ctrloptions); |
537 |
EG2ControllerReleaseInfluence = GIG_EG_CTR_RELEASE_INFLUENCE_EXTRACT(eg2ctrloptions); |
538 |
LFO1Frequency = (double) GIG_EXP_DECODE(_3ewa->ReadInt32()); |
539 |
EG2Attack = (double) GIG_EXP_DECODE(_3ewa->ReadInt32()); |
540 |
EG2Decay1 = (double) GIG_EXP_DECODE(_3ewa->ReadInt32()); |
541 |
_3ewa->ReadInt16(); // unknown |
542 |
EG2Sustain = _3ewa->ReadUint16(); |
543 |
EG2Release = (double) GIG_EXP_DECODE(_3ewa->ReadInt32()); |
544 |
_3ewa->ReadInt16(); // unknown |
545 |
LFO2ControlDepth = _3ewa->ReadUint16(); |
546 |
LFO2Frequency = (double) GIG_EXP_DECODE(_3ewa->ReadInt32()); |
547 |
_3ewa->ReadInt16(); // unknown |
548 |
LFO2InternalDepth = _3ewa->ReadUint16(); |
549 |
int32_t eg1decay2 = _3ewa->ReadInt32(); |
550 |
EG1Decay2 = (double) GIG_EXP_DECODE(eg1decay2); |
551 |
EG1InfiniteSustain = (eg1decay2 == 0x7fffffff); |
552 |
_3ewa->ReadInt16(); // unknown |
553 |
EG1PreAttack = _3ewa->ReadUint16(); |
554 |
int32_t eg2decay2 = _3ewa->ReadInt32(); |
555 |
EG2Decay2 = (double) GIG_EXP_DECODE(eg2decay2); |
556 |
EG2InfiniteSustain = (eg2decay2 == 0x7fffffff); |
557 |
_3ewa->ReadInt16(); // unknown |
558 |
EG2PreAttack = _3ewa->ReadUint16(); |
559 |
uint8_t velocityresponse = _3ewa->ReadUint8(); |
560 |
if (velocityresponse < 5) { |
561 |
VelocityResponseCurve = curve_type_nonlinear; |
562 |
VelocityResponseDepth = velocityresponse; |
563 |
} |
564 |
else if (velocityresponse < 10) { |
565 |
VelocityResponseCurve = curve_type_linear; |
566 |
VelocityResponseDepth = velocityresponse - 5; |
567 |
} |
568 |
else if (velocityresponse < 15) { |
569 |
VelocityResponseCurve = curve_type_special; |
570 |
VelocityResponseDepth = velocityresponse - 10; |
571 |
} |
572 |
else { |
573 |
VelocityResponseCurve = curve_type_unknown; |
574 |
VelocityResponseDepth = 0; |
575 |
} |
576 |
uint8_t releasevelocityresponse = _3ewa->ReadUint8(); |
577 |
if (releasevelocityresponse < 5) { |
578 |
ReleaseVelocityResponseCurve = curve_type_nonlinear; |
579 |
ReleaseVelocityResponseDepth = releasevelocityresponse; |
580 |
} |
581 |
else if (releasevelocityresponse < 10) { |
582 |
ReleaseVelocityResponseCurve = curve_type_linear; |
583 |
ReleaseVelocityResponseDepth = releasevelocityresponse - 5; |
584 |
} |
585 |
else if (releasevelocityresponse < 15) { |
586 |
ReleaseVelocityResponseCurve = curve_type_special; |
587 |
ReleaseVelocityResponseDepth = releasevelocityresponse - 10; |
588 |
} |
589 |
else { |
590 |
ReleaseVelocityResponseCurve = curve_type_unknown; |
591 |
ReleaseVelocityResponseDepth = 0; |
592 |
} |
593 |
VelocityResponseCurveScaling = _3ewa->ReadUint8(); |
594 |
AttenuationControlTreshold = _3ewa->ReadInt8(); |
595 |
_3ewa->ReadInt32(); // unknown |
596 |
SampleStartOffset = (uint16_t) _3ewa->ReadInt16(); |
597 |
_3ewa->ReadInt16(); // unknown |
598 |
uint8_t pitchTrackDimensionBypass = _3ewa->ReadInt8(); |
599 |
PitchTrack = GIG_PITCH_TRACK_EXTRACT(pitchTrackDimensionBypass); |
600 |
if (pitchTrackDimensionBypass & 0x10) DimensionBypass = dim_bypass_ctrl_94; |
601 |
else if (pitchTrackDimensionBypass & 0x20) DimensionBypass = dim_bypass_ctrl_95; |
602 |
else DimensionBypass = dim_bypass_ctrl_none; |
603 |
uint8_t pan = _3ewa->ReadUint8(); |
604 |
Pan = (pan < 64) ? pan : (-1) * (int8_t)pan - 63; |
605 |
SelfMask = _3ewa->ReadInt8() & 0x01; |
606 |
_3ewa->ReadInt8(); // unknown |
607 |
uint8_t lfo3ctrl = _3ewa->ReadUint8(); |
608 |
LFO3Controller = static_cast<lfo3_ctrl_t>(lfo3ctrl & 0x07); // lower 3 bits |
609 |
LFO3Sync = lfo3ctrl & 0x20; // bit 5 |
610 |
InvertAttenuationControl = lfo3ctrl & 0x80; // bit 7 |
611 |
if (VCFType == vcf_type_lowpass) { |
612 |
if (lfo3ctrl & 0x40) // bit 6 |
613 |
VCFType = vcf_type_lowpassturbo; |
614 |
} |
615 |
AttenuationControl = static_cast<attenuation_ctrl_t>(_3ewa->ReadUint8()); |
616 |
uint8_t lfo2ctrl = _3ewa->ReadUint8(); |
617 |
LFO2Controller = static_cast<lfo2_ctrl_t>(lfo2ctrl & 0x07); // lower 3 bits |
618 |
LFO2FlipPhase = lfo2ctrl & 0x80; // bit 7 |
619 |
LFO2Sync = lfo2ctrl & 0x20; // bit 5 |
620 |
bool extResonanceCtrl = lfo2ctrl & 0x40; // bit 6 |
621 |
uint8_t lfo1ctrl = _3ewa->ReadUint8(); |
622 |
LFO1Controller = static_cast<lfo1_ctrl_t>(lfo1ctrl & 0x07); // lower 3 bits |
623 |
LFO1FlipPhase = lfo1ctrl & 0x80; // bit 7 |
624 |
LFO1Sync = lfo1ctrl & 0x40; // bit 6 |
625 |
VCFResonanceController = (extResonanceCtrl) ? static_cast<vcf_res_ctrl_t>(GIG_VCF_RESONANCE_CTRL_EXTRACT(lfo1ctrl)) |
626 |
: vcf_res_ctrl_none; |
627 |
uint16_t eg3depth = _3ewa->ReadUint16(); |
628 |
EG3Depth = (eg3depth <= 1200) ? eg3depth /* positives */ |
629 |
: (-1) * (int16_t) ((eg3depth ^ 0xffff) + 1); /* binary complementary for negatives */ |
630 |
_3ewa->ReadInt16(); // unknown |
631 |
ChannelOffset = _3ewa->ReadUint8() / 4; |
632 |
uint8_t regoptions = _3ewa->ReadUint8(); |
633 |
MSDecode = regoptions & 0x01; // bit 0 |
634 |
SustainDefeat = regoptions & 0x02; // bit 1 |
635 |
_3ewa->ReadInt16(); // unknown |
636 |
VelocityUpperLimit = _3ewa->ReadInt8(); |
637 |
_3ewa->ReadInt8(); // unknown |
638 |
_3ewa->ReadInt16(); // unknown |
639 |
ReleaseTriggerDecay = _3ewa->ReadUint8(); // release trigger decay |
640 |
_3ewa->ReadInt8(); // unknown |
641 |
_3ewa->ReadInt8(); // unknown |
642 |
EG1Hold = _3ewa->ReadUint8() & 0x80; // bit 7 |
643 |
uint8_t vcfcutoff = _3ewa->ReadUint8(); |
644 |
VCFEnabled = vcfcutoff & 0x80; // bit 7 |
645 |
VCFCutoff = vcfcutoff & 0x7f; // lower 7 bits |
646 |
VCFCutoffController = static_cast<vcf_cutoff_ctrl_t>(_3ewa->ReadUint8()); |
647 |
VCFVelocityScale = _3ewa->ReadUint8(); |
648 |
_3ewa->ReadInt8(); // unknown |
649 |
uint8_t vcfresonance = _3ewa->ReadUint8(); |
650 |
VCFResonance = vcfresonance & 0x7f; // lower 7 bits |
651 |
VCFResonanceDynamic = !(vcfresonance & 0x80); // bit 7 |
652 |
uint8_t vcfbreakpoint = _3ewa->ReadUint8(); |
653 |
VCFKeyboardTracking = vcfbreakpoint & 0x80; // bit 7 |
654 |
VCFKeyboardTrackingBreakpoint = vcfbreakpoint & 0x7f; // lower 7 bits |
655 |
uint8_t vcfvelocity = _3ewa->ReadUint8(); |
656 |
VCFVelocityDynamicRange = vcfvelocity % 5; |
657 |
VCFVelocityCurve = static_cast<curve_type_t>(vcfvelocity / 5); |
658 |
VCFType = static_cast<vcf_type_t>(_3ewa->ReadUint8()); |
659 |
|
660 |
// get the corresponding velocity->volume table from the table map or create & calculate that table if it doesn't exist yet |
661 |
uint32_t tableKey = (VelocityResponseCurve<<16) | (VelocityResponseDepth<<8) | VelocityResponseCurveScaling; |
662 |
if (pVelocityTables->count(tableKey)) { // if key exists |
663 |
pVelocityAttenuationTable = (*pVelocityTables)[tableKey]; |
664 |
} |
665 |
else { |
666 |
pVelocityAttenuationTable = new double[128]; |
667 |
switch (VelocityResponseCurve) { // calculate the new table |
668 |
case curve_type_nonlinear: |
669 |
for (int velocity = 0; velocity < 128; velocity++) { |
670 |
pVelocityAttenuationTable[velocity] = |
671 |
GIG_VELOCITY_TRANSFORM_NONLINEAR((double)(velocity+1),(double)(VelocityResponseDepth+1),(double)VelocityResponseCurveScaling); |
672 |
if (pVelocityAttenuationTable[velocity] > 1.0) pVelocityAttenuationTable[velocity] = 1.0; |
673 |
else if (pVelocityAttenuationTable[velocity] < 0.0) pVelocityAttenuationTable[velocity] = 0.0; |
674 |
} |
675 |
break; |
676 |
case curve_type_linear: |
677 |
for (int velocity = 0; velocity < 128; velocity++) { |
678 |
pVelocityAttenuationTable[velocity] = |
679 |
GIG_VELOCITY_TRANSFORM_LINEAR((double)velocity,(double)(VelocityResponseDepth+1),(double)VelocityResponseCurveScaling); |
680 |
if (pVelocityAttenuationTable[velocity] > 1.0) pVelocityAttenuationTable[velocity] = 1.0; |
681 |
else if (pVelocityAttenuationTable[velocity] < 0.0) pVelocityAttenuationTable[velocity] = 0.0; |
682 |
} |
683 |
break; |
684 |
case curve_type_special: |
685 |
for (int velocity = 0; velocity < 128; velocity++) { |
686 |
pVelocityAttenuationTable[velocity] = |
687 |
GIG_VELOCITY_TRANSFORM_SPECIAL((double)(velocity+1),(double)(VelocityResponseDepth+1),(double)VelocityResponseCurveScaling); |
688 |
if (pVelocityAttenuationTable[velocity] > 1.0) pVelocityAttenuationTable[velocity] = 1.0; |
689 |
else if (pVelocityAttenuationTable[velocity] < 0.0) pVelocityAttenuationTable[velocity] = 0.0; |
690 |
} |
691 |
break; |
692 |
case curve_type_unknown: |
693 |
default: |
694 |
throw gig::Exception("Unknown transform curve type."); |
695 |
} |
696 |
(*pVelocityTables)[tableKey] = pVelocityAttenuationTable; // put the new table into the tables map |
697 |
} |
698 |
} |
699 |
|
700 |
DimensionRegion::~DimensionRegion() { |
701 |
Instances--; |
702 |
if (!Instances) { |
703 |
// delete the velocity->volume tables |
704 |
VelocityTableMap::iterator iter; |
705 |
for (iter = pVelocityTables->begin(); iter != pVelocityTables->end(); iter++) { |
706 |
double* pTable = iter->second; |
707 |
if (pTable) delete[] pTable; |
708 |
} |
709 |
pVelocityTables->clear(); |
710 |
delete pVelocityTables; |
711 |
pVelocityTables = NULL; |
712 |
} |
713 |
} |
714 |
|
715 |
/** |
716 |
* Returns the correct amplitude factor for the given \a MIDIKeyVelocity. |
717 |
* All involved parameters (VelocityResponseCurve, VelocityResponseDepth |
718 |
* and VelocityResponseCurveScaling) involved are taken into account to |
719 |
* calculate the amplitude factor. Use this method when a key was |
720 |
* triggered to get the volume with which the sample should be played |
721 |
* back. |
722 |
* |
723 |
* @param MIDI velocity value of the triggered key (between 0 and 127) |
724 |
* @returns amplitude factor (between 0.0 and 1.0) |
725 |
*/ |
726 |
double DimensionRegion::GetVelocityAttenuation(uint8_t MIDIKeyVelocity) { |
727 |
return pVelocityAttenuationTable[MIDIKeyVelocity]; |
728 |
} |
729 |
|
730 |
|
731 |
|
732 |
// *************** Region *************** |
733 |
// * |
734 |
|
735 |
Region::Region(Instrument* pInstrument, RIFF::List* rgnList) : DLS::Region((DLS::Instrument*) pInstrument, rgnList) { |
736 |
// Initialization |
737 |
Dimensions = 0; |
738 |
for (int i = 0; i < 32; i++) { |
739 |
pDimensionRegions[i] = NULL; |
740 |
} |
741 |
|
742 |
// Actual Loading |
743 |
|
744 |
LoadDimensionRegions(rgnList); |
745 |
|
746 |
RIFF::Chunk* _3lnk = rgnList->GetSubChunk(CHUNK_ID_3LNK); |
747 |
if (_3lnk) { |
748 |
DimensionRegions = _3lnk->ReadUint32(); |
749 |
for (int i = 0; i < 5; i++) { |
750 |
dimension_t dimension = static_cast<dimension_t>(_3lnk->ReadUint8()); |
751 |
uint8_t bits = _3lnk->ReadUint8(); |
752 |
if (dimension == dimension_none) { // inactive dimension |
753 |
pDimensionDefinitions[i].dimension = dimension_none; |
754 |
pDimensionDefinitions[i].bits = 0; |
755 |
pDimensionDefinitions[i].zones = 0; |
756 |
pDimensionDefinitions[i].split_type = split_type_bit; |
757 |
pDimensionDefinitions[i].ranges = NULL; |
758 |
pDimensionDefinitions[i].zone_size = 0; |
759 |
} |
760 |
else { // active dimension |
761 |
pDimensionDefinitions[i].dimension = dimension; |
762 |
pDimensionDefinitions[i].bits = bits; |
763 |
pDimensionDefinitions[i].zones = 0x01 << bits; // = pow(2,bits) |
764 |
pDimensionDefinitions[i].split_type = (dimension == dimension_layer || |
765 |
dimension == dimension_samplechannel) ? split_type_bit |
766 |
: split_type_normal; |
767 |
pDimensionDefinitions[i].ranges = NULL; // it's not possible to check velocity dimensions for custom defined ranges at this point |
768 |
pDimensionDefinitions[i].zone_size = |
769 |
(pDimensionDefinitions[i].split_type == split_type_normal) ? 128 / pDimensionDefinitions[i].zones |
770 |
: 0; |
771 |
Dimensions++; |
772 |
} |
773 |
_3lnk->SetPos(6, RIFF::stream_curpos); // jump forward to next dimension definition |
774 |
} |
775 |
|
776 |
// check velocity dimension (if there is one) for custom defined zone ranges |
777 |
for (uint i = 0; i < Dimensions; i++) { |
778 |
dimension_def_t* pDimDef = pDimensionDefinitions + i; |
779 |
if (pDimDef->dimension == dimension_velocity) { |
780 |
if (pDimensionRegions[0]->VelocityUpperLimit == 0) { |
781 |
// no custom defined ranges |
782 |
pDimDef->split_type = split_type_normal; |
783 |
pDimDef->ranges = NULL; |
784 |
} |
785 |
else { // custom defined ranges |
786 |
pDimDef->split_type = split_type_customvelocity; |
787 |
pDimDef->ranges = new range_t[pDimDef->zones]; |
788 |
unsigned int bits[5] = {0,0,0,0,0}; |
789 |
int previousUpperLimit = -1; |
790 |
for (int velocityZone = 0; velocityZone < pDimDef->zones; velocityZone++) { |
791 |
bits[i] = velocityZone; |
792 |
DimensionRegion* pDimRegion = GetDimensionRegionByBit(bits[4],bits[3],bits[2],bits[1],bits[0]); |
793 |
|
794 |
pDimDef->ranges[velocityZone].low = previousUpperLimit + 1; |
795 |
pDimDef->ranges[velocityZone].high = pDimRegion->VelocityUpperLimit; |
796 |
previousUpperLimit = pDimDef->ranges[velocityZone].high; |
797 |
// fill velocity table |
798 |
for (int i = pDimDef->ranges[velocityZone].low; i <= pDimDef->ranges[velocityZone].high; i++) { |
799 |
VelocityTable[i] = velocityZone; |
800 |
} |
801 |
} |
802 |
} |
803 |
} |
804 |
} |
805 |
|
806 |
// load sample references |
807 |
_3lnk->SetPos(44); // jump to start of the wave pool indices (if not already there) |
808 |
for (uint i = 0; i < DimensionRegions; i++) { |
809 |
uint32_t wavepoolindex = _3lnk->ReadUint32(); |
810 |
pDimensionRegions[i]->pSample = GetSampleFromWavePool(wavepoolindex); |
811 |
} |
812 |
} |
813 |
else throw gig::Exception("Mandatory <3lnk> chunk not found."); |
814 |
} |
815 |
|
816 |
void Region::LoadDimensionRegions(RIFF::List* rgn) { |
817 |
RIFF::List* _3prg = rgn->GetSubList(LIST_TYPE_3PRG); |
818 |
if (_3prg) { |
819 |
int dimensionRegionNr = 0; |
820 |
RIFF::List* _3ewl = _3prg->GetFirstSubList(); |
821 |
while (_3ewl) { |
822 |
if (_3ewl->GetListType() == LIST_TYPE_3EWL) { |
823 |
pDimensionRegions[dimensionRegionNr] = new DimensionRegion(_3ewl); |
824 |
dimensionRegionNr++; |
825 |
} |
826 |
_3ewl = _3prg->GetNextSubList(); |
827 |
} |
828 |
if (dimensionRegionNr == 0) throw gig::Exception("No dimension region found."); |
829 |
} |
830 |
} |
831 |
|
832 |
Region::~Region() { |
833 |
for (uint i = 0; i < Dimensions; i++) { |
834 |
if (pDimensionDefinitions[i].ranges) delete[] pDimensionDefinitions[i].ranges; |
835 |
} |
836 |
for (int i = 0; i < 32; i++) { |
837 |
if (pDimensionRegions[i]) delete pDimensionRegions[i]; |
838 |
} |
839 |
} |
840 |
|
841 |
/** |
842 |
* Use this method in your audio engine to get the appropriate dimension |
843 |
* region with it's articulation data for the current situation. Just |
844 |
* call the method with the current MIDI controller values and you'll get |
845 |
* the DimensionRegion with the appropriate articulation data for the |
846 |
* current situation (for this Region of course only). To do that you'll |
847 |
* first have to look which dimensions with which controllers and in |
848 |
* which order are defined for this Region when you load the .gig file. |
849 |
* Special cases are e.g. layer or channel dimensions where you just put |
850 |
* in the index numbers instead of a MIDI controller value (means 0 for |
851 |
* left channel, 1 for right channel or 0 for layer 0, 1 for layer 1, |
852 |
* etc.). |
853 |
* |
854 |
* @param Dim4Val MIDI controller value (0-127) for dimension 4 |
855 |
* @param Dim3Val MIDI controller value (0-127) for dimension 3 |
856 |
* @param Dim2Val MIDI controller value (0-127) for dimension 2 |
857 |
* @param Dim1Val MIDI controller value (0-127) for dimension 1 |
858 |
* @param Dim0Val MIDI controller value (0-127) for dimension 0 |
859 |
* @returns adress to the DimensionRegion for the given situation |
860 |
* @see pDimensionDefinitions |
861 |
* @see Dimensions |
862 |
*/ |
863 |
DimensionRegion* Region::GetDimensionRegionByValue(uint Dim4Val, uint Dim3Val, uint Dim2Val, uint Dim1Val, uint Dim0Val) { |
864 |
unsigned int bits[5] = {Dim0Val,Dim1Val,Dim2Val,Dim3Val,Dim4Val}; |
865 |
for (uint i = 0; i < Dimensions; i++) { |
866 |
switch (pDimensionDefinitions[i].split_type) { |
867 |
case split_type_normal: |
868 |
bits[i] /= pDimensionDefinitions[i].zone_size; |
869 |
break; |
870 |
case split_type_customvelocity: |
871 |
bits[i] = VelocityTable[bits[i]]; |
872 |
break; |
873 |
// else the value is already the sought dimension bit number |
874 |
} |
875 |
} |
876 |
return GetDimensionRegionByBit(bits[4],bits[3],bits[2],bits[1],bits[0]); |
877 |
} |
878 |
|
879 |
/** |
880 |
* Returns the appropriate DimensionRegion for the given dimension bit |
881 |
* numbers (zone index). You usually use <i>GetDimensionRegionByValue</i> |
882 |
* instead of calling this method directly! |
883 |
* |
884 |
* @param Dim4Bit Bit number for dimension 4 |
885 |
* @param Dim3Bit Bit number for dimension 3 |
886 |
* @param Dim2Bit Bit number for dimension 2 |
887 |
* @param Dim1Bit Bit number for dimension 1 |
888 |
* @param Dim0Bit Bit number for dimension 0 |
889 |
* @returns adress to the DimensionRegion for the given dimension |
890 |
* bit numbers |
891 |
* @see GetDimensionRegionByValue() |
892 |
*/ |
893 |
DimensionRegion* Region::GetDimensionRegionByBit(uint8_t Dim4Bit, uint8_t Dim3Bit, uint8_t Dim2Bit, uint8_t Dim1Bit, uint8_t Dim0Bit) { |
894 |
return *(pDimensionRegions + ((((((((Dim4Bit << pDimensionDefinitions[3].bits) | Dim3Bit) |
895 |
<< pDimensionDefinitions[2].bits) | Dim2Bit) |
896 |
<< pDimensionDefinitions[1].bits) | Dim1Bit) |
897 |
<< pDimensionDefinitions[0].bits) | Dim0Bit) ); |
898 |
} |
899 |
|
900 |
/** |
901 |
* Returns pointer address to the Sample referenced with this region. |
902 |
* This is the global Sample for the entire Region (not sure if this is |
903 |
* actually used by the Gigasampler engine - I would only use the Sample |
904 |
* referenced by the appropriate DimensionRegion instead of this sample). |
905 |
* |
906 |
* @returns address to Sample or NULL if there is no reference to a |
907 |
* sample saved in the .gig file |
908 |
*/ |
909 |
Sample* Region::GetSample() { |
910 |
if (pSample) return static_cast<gig::Sample*>(pSample); |
911 |
else return static_cast<gig::Sample*>(pSample = GetSampleFromWavePool(WavePoolTableIndex)); |
912 |
} |
913 |
|
914 |
Sample* Region::GetSampleFromWavePool(unsigned int WavePoolTableIndex) { |
915 |
File* file = (File*) GetParent()->GetParent(); |
916 |
unsigned long soughtoffset = file->pWavePoolTable[WavePoolTableIndex]; |
917 |
Sample* sample = file->GetFirstSample(); |
918 |
while (sample) { |
919 |
if (sample->ulWavePoolOffset == soughtoffset) return static_cast<gig::Sample*>(pSample = sample); |
920 |
sample = file->GetNextSample(); |
921 |
} |
922 |
return NULL; |
923 |
} |
924 |
|
925 |
|
926 |
|
927 |
// *************** Instrument *************** |
928 |
// * |
929 |
|
930 |
Instrument::Instrument(File* pFile, RIFF::List* insList) : DLS::Instrument((DLS::File*)pFile, insList) { |
931 |
// Initialization |
932 |
for (int i = 0; i < 128; i++) RegionKeyTable[i] = NULL; |
933 |
RegionIndex = -1; |
934 |
|
935 |
// Loading |
936 |
RIFF::List* lart = insList->GetSubList(LIST_TYPE_LART); |
937 |
if (lart) { |
938 |
RIFF::Chunk* _3ewg = lart->GetSubChunk(CHUNK_ID_3EWG); |
939 |
if (_3ewg) { |
940 |
EffectSend = _3ewg->ReadUint16(); |
941 |
Attenuation = _3ewg->ReadInt32(); |
942 |
FineTune = _3ewg->ReadInt16(); |
943 |
PitchbendRange = _3ewg->ReadInt16(); |
944 |
uint8_t dimkeystart = _3ewg->ReadUint8(); |
945 |
PianoReleaseMode = dimkeystart & 0x01; |
946 |
DimensionKeyRange.low = dimkeystart >> 1; |
947 |
DimensionKeyRange.high = _3ewg->ReadUint8(); |
948 |
} |
949 |
else throw gig::Exception("Mandatory <3ewg> chunk not found."); |
950 |
} |
951 |
else throw gig::Exception("Mandatory <lart> list chunk not found."); |
952 |
|
953 |
RIFF::List* lrgn = insList->GetSubList(LIST_TYPE_LRGN); |
954 |
if (!lrgn) throw gig::Exception("Mandatory chunks in <ins > chunk not found."); |
955 |
pRegions = new Region*[Regions]; |
956 |
RIFF::List* rgn = lrgn->GetFirstSubList(); |
957 |
unsigned int iRegion = 0; |
958 |
while (rgn) { |
959 |
if (rgn->GetListType() == LIST_TYPE_RGN) { |
960 |
pRegions[iRegion] = new Region(this, rgn); |
961 |
iRegion++; |
962 |
} |
963 |
rgn = lrgn->GetNextSubList(); |
964 |
} |
965 |
|
966 |
// Creating Region Key Table for fast lookup |
967 |
for (uint iReg = 0; iReg < Regions; iReg++) { |
968 |
for (int iKey = pRegions[iReg]->KeyRange.low; iKey <= pRegions[iReg]->KeyRange.high; iKey++) { |
969 |
RegionKeyTable[iKey] = pRegions[iReg]; |
970 |
} |
971 |
} |
972 |
} |
973 |
|
974 |
Instrument::~Instrument() { |
975 |
for (uint i = 0; i < Regions; i++) { |
976 |
if (pRegions) { |
977 |
if (pRegions[i]) delete (pRegions[i]); |
978 |
} |
979 |
delete[] pRegions; |
980 |
} |
981 |
} |
982 |
|
983 |
/** |
984 |
* Returns the appropriate Region for a triggered note. |
985 |
* |
986 |
* @param Key MIDI Key number of triggered note / key (0 - 127) |
987 |
* @returns pointer adress to the appropriate Region or NULL if there |
988 |
* there is no Region defined for the given \a Key |
989 |
*/ |
990 |
Region* Instrument::GetRegion(unsigned int Key) { |
991 |
if (!pRegions || Key > 127) return NULL; |
992 |
return RegionKeyTable[Key]; |
993 |
/*for (int i = 0; i < Regions; i++) { |
994 |
if (Key <= pRegions[i]->KeyRange.high && |
995 |
Key >= pRegions[i]->KeyRange.low) return pRegions[i]; |
996 |
} |
997 |
return NULL;*/ |
998 |
} |
999 |
|
1000 |
/** |
1001 |
* Returns the first Region of the instrument. You have to call this |
1002 |
* method once before you use GetNextRegion(). |
1003 |
* |
1004 |
* @returns pointer address to first region or NULL if there is none |
1005 |
* @see GetNextRegion() |
1006 |
*/ |
1007 |
Region* Instrument::GetFirstRegion() { |
1008 |
if (!Regions) return NULL; |
1009 |
RegionIndex = 1; |
1010 |
return pRegions[0]; |
1011 |
} |
1012 |
|
1013 |
/** |
1014 |
* Returns the next Region of the instrument. You have to call |
1015 |
* GetFirstRegion() once before you can use this method. By calling this |
1016 |
* method multiple times it iterates through the available Regions. |
1017 |
* |
1018 |
* @returns pointer address to the next region or NULL if end reached |
1019 |
* @see GetFirstRegion() |
1020 |
*/ |
1021 |
Region* Instrument::GetNextRegion() { |
1022 |
if (RegionIndex < 0 || RegionIndex >= Regions) return NULL; |
1023 |
return pRegions[RegionIndex++]; |
1024 |
} |
1025 |
|
1026 |
|
1027 |
|
1028 |
// *************** File *************** |
1029 |
// * |
1030 |
|
1031 |
File::File(RIFF::File* pRIFF) : DLS::File(pRIFF) { |
1032 |
pSamples = NULL; |
1033 |
pInstruments = NULL; |
1034 |
} |
1035 |
|
1036 |
Sample* File::GetFirstSample() { |
1037 |
if (!pSamples) LoadSamples(); |
1038 |
if (!pSamples) return NULL; |
1039 |
SamplesIterator = pSamples->begin(); |
1040 |
return static_cast<gig::Sample*>( (SamplesIterator != pSamples->end()) ? *SamplesIterator : NULL ); |
1041 |
} |
1042 |
|
1043 |
Sample* File::GetNextSample() { |
1044 |
if (!pSamples) return NULL; |
1045 |
SamplesIterator++; |
1046 |
return static_cast<gig::Sample*>( (SamplesIterator != pSamples->end()) ? *SamplesIterator : NULL ); |
1047 |
} |
1048 |
|
1049 |
void File::LoadSamples() { |
1050 |
RIFF::List* wvpl = pRIFF->GetSubList(LIST_TYPE_WVPL); |
1051 |
if (wvpl) { |
1052 |
unsigned long wvplFileOffset = wvpl->GetFilePos(); |
1053 |
RIFF::List* wave = wvpl->GetFirstSubList(); |
1054 |
while (wave) { |
1055 |
if (wave->GetListType() == LIST_TYPE_WAVE) { |
1056 |
if (!pSamples) pSamples = new SampleList; |
1057 |
unsigned long waveFileOffset = wave->GetFilePos(); |
1058 |
pSamples->push_back(new Sample(this, wave, waveFileOffset - wvplFileOffset)); |
1059 |
} |
1060 |
wave = wvpl->GetNextSubList(); |
1061 |
} |
1062 |
} |
1063 |
else throw gig::Exception("Mandatory <wvpl> chunk not found."); |
1064 |
} |
1065 |
|
1066 |
Instrument* File::GetFirstInstrument() { |
1067 |
if (!pInstruments) LoadInstruments(); |
1068 |
if (!pInstruments) return NULL; |
1069 |
InstrumentsIterator = pInstruments->begin(); |
1070 |
return (InstrumentsIterator != pInstruments->end()) ? *InstrumentsIterator : NULL; |
1071 |
} |
1072 |
|
1073 |
Instrument* File::GetNextInstrument() { |
1074 |
if (!pInstruments) return NULL; |
1075 |
InstrumentsIterator++; |
1076 |
return (InstrumentsIterator != pInstruments->end()) ? *InstrumentsIterator : NULL; |
1077 |
} |
1078 |
|
1079 |
/** |
1080 |
* Returns the instrument with the given index. |
1081 |
* |
1082 |
* @returns sought instrument or NULL if there's no such instrument |
1083 |
*/ |
1084 |
Instrument* File::GetInstrument(uint index) { |
1085 |
if (!pInstruments) LoadInstruments(); |
1086 |
if (!pInstruments) return NULL; |
1087 |
InstrumentsIterator = pInstruments->begin(); |
1088 |
for (uint i = 0; InstrumentsIterator != pInstruments->end(); i++) { |
1089 |
if (i == index) return *InstrumentsIterator; |
1090 |
InstrumentsIterator++; |
1091 |
} |
1092 |
return NULL; |
1093 |
} |
1094 |
|
1095 |
void File::LoadInstruments() { |
1096 |
RIFF::List* lstInstruments = pRIFF->GetSubList(LIST_TYPE_LINS); |
1097 |
if (lstInstruments) { |
1098 |
RIFF::List* lstInstr = lstInstruments->GetFirstSubList(); |
1099 |
while (lstInstr) { |
1100 |
if (lstInstr->GetListType() == LIST_TYPE_INS) { |
1101 |
if (!pInstruments) pInstruments = new InstrumentList; |
1102 |
pInstruments->push_back(new Instrument(this, lstInstr)); |
1103 |
} |
1104 |
lstInstr = lstInstruments->GetNextSubList(); |
1105 |
} |
1106 |
} |
1107 |
else throw gig::Exception("Mandatory <lins> list chunk not found."); |
1108 |
} |
1109 |
|
1110 |
|
1111 |
|
1112 |
// *************** Exception *************** |
1113 |
// * |
1114 |
|
1115 |
Exception::Exception(String Message) : DLS::Exception(Message) { |
1116 |
} |
1117 |
|
1118 |
void Exception::PrintMessage() { |
1119 |
std::cout << "gig::Exception: " << Message << std::endl; |
1120 |
} |
1121 |
|
1122 |
} // namespace gig |