#include "stdsound.h" #include "nel/sound/complex_sound.h" #include "nel/misc/path.h" #include "nel/misc/common.h" #include "nel/sound/audio_mixer_user.h" #include using namespace std; using namespace NLMISC; namespace NLSOUND { bool CComplexSound::isDetailed() const { return false; } void CComplexSound::parseSequence(const std::string &str, std::vector &seq, uint scale) { seq.clear(); uint32 tmp; string val; string::const_iterator first(str.begin()), last(str.end()); for (; first != last; ++first) { if (*first != ';') val += *first; else { fromString(val, tmp); seq.push_back(tmp * scale); val.clear(); } } // parse the last value if (!val.empty()) { fromString(val, tmp); seq.push_back(tmp * scale); } } void CComplexSound::getSubSoundList(std::vector > &subsounds) const { CAudioMixerUser *mixer = CAudioMixerUser::instance(); std::vector::const_iterator first(_Sounds.begin()), last(_Sounds.end()); for (; first != last; ++first) { CSound *sound = mixer->getSoundId(*first); subsounds.push_back(make_pair(CStringMapper::unmap(*first), sound)); } } uint32 CComplexSound::getDuration() { // evaluate the duration of the sound... if (_DurationValid) return _Duration; // catch the duration of all sub sound. CAudioMixerUser *mixer = CAudioMixerUser::instance(); vector durations; std::vector::iterator first(_Sounds.begin()), last(_Sounds.end()); for (; first != last; ++first) { CSound *sound = mixer->getSoundId(*first); if (sound != NULL) { durations.push_back(sint32(sound->getDuration())); } else durations.push_back(0); } _Duration = 0; switch (_PatternMode) { case MODE_CHAINED: { // sum the duration minus the xfade time (this is an aproximation if sample are shorter than 2 xfade time) vector::iterator first(_SoundSeq.begin()), last(_SoundSeq.end()), prev; for (; first != last; ++first) { if (first != _SoundSeq.begin() && !durations.empty()) { // remove a xfade value _Duration -= minof(uint32(_XFadeLenght / _TicksPerSeconds), durations[*first % durations.size()] / 2, durations[*prev % durations.size()] /2); } if (!durations.empty()) _Duration += durations[*first % durations.size()]; prev = first; } // _Duration -= max(sint(0), sint(_XFadeLenght * (_SoundSeq.size()-2) )); } break; case MODE_SPARSE: { if (_SoundSeq.empty()) _Duration = 0; else if (_DelaySeq.empty()) { _Duration = durations[0]; } else if (_DelaySeq.size() == 1) { _Duration = durations[0] + _DelaySeq[0]; } else { uint soundIndex = 0; _Duration = 0; //durations[soundIndex++]; std::vector::iterator first(_DelaySeq.begin()), last(_DelaySeq.end()); _Duration+= *first; ++first; for (; first != last; ++first) { // add the sound lenght _Duration += durations[soundIndex++ % durations.size()]; // add the delay _Duration += uint32(*first / _TicksPerSeconds); } } } break; case MODE_ALL_IN_ONE: // only find the longueur sound. if (!durations.empty()) _Duration = *(std::max_element(durations.begin(), durations.end())); else _Duration = 0; break; default: return 0; } _DurationValid = true; return _Duration; } // ******************************************************** CComplexSound::CComplexSound() : _PatternMode(CComplexSound::MODE_UNDEFINED), _TicksPerSeconds(1.0f), _XFadeLenght(3000), // default to 3000 sec. _MaxDistValid(false), _Duration(0), _DurationValid(false) { } // ******************************************************** CComplexSound::~CComplexSound() { /* if (_VolumeEnvelope != 0) { delete _VolumeEnvelope; } if (_FreqModulation != 0) { delete _FreqModulation; } */ } float CComplexSound::getMaxDistance() const { if (!_MaxDistValid) { // compute the max distance by checking the max distance of all sounds. CAudioMixerUser *mixer = CAudioMixerUser::instance(); // Hum, getMaxDistance is const, but we must compute the real max dist and update it ! CComplexSound *This = const_cast(this); This->_MaxDist = 0.0f; std::vector::const_iterator first(_Sounds.begin()), last(_Sounds.end()); for (; first != last; ++first) { CSound *sound = mixer->getSoundId(*first); if( sound != NULL) { This->_MaxDist = max(_MaxDist, sound->getMaxDistance()); } } // security check. if (_MaxDist == 0.0f) This->_MaxDist = 1000000.0f; } _MaxDistValid = true; return _MaxDist; } void CComplexSound::serial(NLMISC::IStream &s) { CSound::serial(s); s.serialEnum(_PatternMode); if (s.isReading()) { uint32 nb; s.serial(nb); for (uint i=0; igetDfnName(dfnName); nlassert(dfnName == "complex_sound.dfn"); // Call the base class CSound::importForm(filename, formRoot); // Beat per second. formRoot.getValueByName(_TicksPerSeconds, ".SoundType.Beat"); //beat can't be null or negative! if (_TicksPerSeconds <= 0.0f) _TicksPerSeconds = 1.0f; // List of sound int this pattern NLGEORGES::UFormElm *psoundsArray; _Sounds.clear(); formRoot.getNodeByName(&psoundsArray, ".SoundType.SoundList"); if (psoundsArray != NULL) { uint size; psoundsArray->getArraySize(size); for (uint i=0; igetArrayValue(soundname, i)) { soundname = CFile::getFilenameWithoutExtension(soundname); _Sounds.push_back(CStringMapper::map(soundname)); } } } // Mode of the complex sound. string mode; formRoot.getValueByName(mode, ".SoundType.Mode"); if (mode == "Chained" || mode == "Sparse") { // XFade lenght formRoot.getValueByName(_XFadeLenght, ".SoundType.XFadeLenght"); // Fade in/out flag. formRoot.getValueByName(_DoFadeIn, ".SoundType.DoFadeIn"); formRoot.getValueByName(_DoFadeOut, ".SoundType.DoFadeOut"); // convert xfade to millisec. _XFadeLenght *= 1000; _PatternMode = MODE_CHAINED; // just read the sequence _SoundSeq.clear(); string str; formRoot.getValueByName(str, ".SoundType.SoundSeq"); parseSequence(str, _SoundSeq); if (mode == "Sparse") { _PatternMode = MODE_SPARSE; // also read the delay sequence _DelaySeq.clear(); string str; formRoot.getValueByName(str, ".SoundType.DelaySeq"); // parse the delay and premult by 1000 (for millisec). parseSequence(str, _DelaySeq, 1000); } } else if (mode == "AllInOne") { _PatternMode = MODE_ALL_IN_ONE; // nothing special to read. } else nlassertex(false, ("Unsupported mode : %s", mode.c_str())); } }