/////////////////////////////////////////////////////////////////////////////////// // Copyright (C) 2017 F4EXB // // written by Edouard Griffiths // // // // This program is free software; you can redistribute it and/or modify // // it under the terms of the GNU General Public License as published by // // the Free Software Foundation as version 3 of the License, or // // // // This program is distributed in the hope that it will be useful, // // but WITHOUT ANY WARRANTY; without even the implied warranty of // // MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the // // GNU General Public License V3 for more details. // // // // You should have received a copy of the GNU General Public License // // along with this program. If not, see . // /////////////////////////////////////////////////////////////////////////////////// #ifndef SDRBASE_DSP_SCOPEVISNG_H_ #define SDRBASE_DSP_SCOPEVISNG_H_ #include #include #include #include #include #include #include #include #include "dsp/dsptypes.h" #include "dsp/basebandsamplesink.h" #include "util/export.h" #include "util/message.h" #include "util/doublebuffer.h" #undef M_PI #define M_PI 3.14159265358979323846 class GLScopeNG; class SDRANGEL_API ScopeVisNG : public BasebandSampleSink { public: enum ProjectionType { ProjectionReal = 0, //!< Extract real part ProjectionImag, //!< Extract imaginary part ProjectionMagLin, //!< Calculate linear magnitude or modulus ProjectionMagDB, //!< Calculate logarithmic (dB) of squared magnitude ProjectionPhase, //!< Calculate phase ProjectionDPhase, //!< Calculate phase derivative i.e. instantaneous frequency scaled to sample rate nbProjectionTypes //!< Gives the number of projections in the enum }; struct TraceData { ProjectionType m_projectionType; //!< Complex to real projection type uint32_t m_inputIndex; //!< Input or feed index this trace is associated with float m_amp; //!< Amplification factor uint32_t m_ampIndex; //!< Index in list of amplification factors float m_ofs; //!< Offset factor int m_ofsCoarse; //!< Coarse offset slider value int m_ofsFine; //!< Fine offset slider value int m_traceDelay; //!< Trace delay in number of samples int m_traceDelayCoarse; //!< Coarse delay slider value int m_traceDelayFine; //!< Fine delay slider value float m_triggerDisplayLevel; //!< Displayable trigger display level in -1:+1 scale. Off scale if not displayable. QColor m_traceColor; //!< Trace display color float m_traceColorR; //!< Trace display color - red shortcut float m_traceColorG; //!< Trace display color - green shortcut float m_traceColorB; //!< Trace display color - blue shortcut bool m_hasTextOverlay; //!< True if a text overlay has to be displayed QString m_textOverlay; //!< Text overlay to display bool m_viewTrace; //!< Trace visibility TraceData() : m_projectionType(ProjectionReal), m_inputIndex(0), m_amp(1.0f), m_ampIndex(0), m_ofs(0.0f), m_ofsCoarse(0), m_ofsFine(0), m_traceDelay(0), m_traceDelayCoarse(0), m_traceDelayFine(0), m_triggerDisplayLevel(2.0), // OVer scale by default (2.0) m_traceColor(255,255,64), m_hasTextOverlay(false), m_viewTrace(true) { setColor(m_traceColor); } void setColor(QColor color) { m_traceColor = color; qreal r,g,b,a; m_traceColor.getRgbF(&r, &g, &b, &a); m_traceColorR = r; m_traceColorG = g; m_traceColorB = b; } }; struct TriggerData { ProjectionType m_projectionType; //!< Complex to real projection type uint32_t m_inputIndex; //!< Input or feed index this trigger is associated with Real m_triggerLevel; //!< Level in real units int m_triggerLevelCoarse; int m_triggerLevelFine; bool m_triggerPositiveEdge; //!< Trigger on the positive edge (else negative) bool m_triggerBothEdges; //!< Trigger on both edges (else only one) uint32_t m_triggerDelay; //!< Delay before the trigger is kicked off in number of samples (trigger delay) double m_triggerDelayMult; //!< Trigger delay as a multiplier of trace length int m_triggerDelayCoarse; int m_triggerDelayFine; uint32_t m_triggerRepeat; //!< Number of trigger conditions before the final decisive trigger QColor m_triggerColor; //!< Trigger line display color float m_triggerColorR; //!< Trigger line display color - red shortcut float m_triggerColorG; //!< Trigger line display color - green shortcut float m_triggerColorB; //!< Trigger line display color - blue shortcut TriggerData() : m_projectionType(ProjectionReal), m_inputIndex(0), m_triggerLevel(0.0f), m_triggerLevelCoarse(0), m_triggerLevelFine(0), m_triggerPositiveEdge(true), m_triggerBothEdges(false), m_triggerDelay(0), m_triggerDelayMult(0.0), m_triggerDelayCoarse(0), m_triggerDelayFine(0), m_triggerRepeat(0), m_triggerColor(0,255,0) { setColor(m_triggerColor); } void setColor(QColor color) { m_triggerColor = color; qreal r,g,b,a; m_triggerColor.getRgbF(&r, &g, &b, &a); m_triggerColorR = r; m_triggerColorG = g; m_triggerColorB = b; } }; static const uint32_t m_traceChunkSize; static const uint32_t m_maxNbTriggers = 10; static const uint32_t m_maxNbTraces = 10; static const uint32_t m_nbTraceMemories = 16; ScopeVisNG(GLScopeNG* glScope = 0); virtual ~ScopeVisNG(); void setSampleRate(int sampleRate); void configure(uint32_t traceSize, uint32_t timeBase, uint32_t timeOfsProMill, uint32_t triggerPre, bool freeRun); void addTrace(const TraceData& traceData); void changeTrace(const TraceData& traceData, uint32_t traceIndex); void removeTrace(uint32_t traceIndex); void moveTrace(uint32_t traceIndex, bool upElseDown); void focusOnTrace(uint32_t traceIndex); void addTrigger(const TriggerData& triggerData); void changeTrigger(const TriggerData& triggerData, uint32_t triggerIndex); void removeTrigger(uint32_t triggerIndex); void moveTrigger(uint32_t triggerIndex, bool upElseDown); void focusOnTrigger(uint32_t triggerIndex); void setOneShot(bool oneShot); void setMemoryIndex(uint32_t memoryIndex); void getTriggerData(TriggerData& triggerData, uint32_t triggerIndex) { if (triggerIndex < m_triggerConditions.size()) { triggerData = m_triggerConditions[triggerIndex].m_triggerData; } } void getTraceData(TraceData& traceData, uint32_t traceIndex) { if (traceIndex < m_traces.m_tracesData.size()) { traceData = m_traces.m_tracesData[traceIndex]; } } const TriggerData& getTriggerData(uint32_t triggerIndex) const { return m_triggerConditions[triggerIndex].m_triggerData; } const std::vector& getTracesData() const { return m_traces.m_tracesData; } uint32_t getNbTriggers() const { return m_triggerConditions.size(); } virtual void feed(const SampleVector::const_iterator& begin, const SampleVector::const_iterator& end, bool positiveOnly); virtual void start(); virtual void stop(); virtual bool handleMessage(const Message& message); SampleVector::const_iterator getTriggerPoint() const { return m_triggerPoint; } private: // === messages === // --------------------------------------------- class MsgConfigureScopeVisNG : public Message { MESSAGE_CLASS_DECLARATION public: static MsgConfigureScopeVisNG* create( uint32_t traceSize, uint32_t timeBase, uint32_t timeOfsProMill, uint32_t triggerPre, bool freeRun) { return new MsgConfigureScopeVisNG(traceSize, timeBase, timeOfsProMill, triggerPre, freeRun); } uint32_t getTraceSize() const { return m_traceSize; } uint32_t getTimeBase() const { return m_timeBase; } uint32_t getTimeOfsProMill() const { return m_timeOfsProMill; } uint32_t getTriggerPre() const { return m_triggerPre; } bool getFreeRun() const { return m_freeRun; } private: uint32_t m_traceSize; uint32_t m_timeBase; uint32_t m_timeOfsProMill; uint32_t m_triggerPre; bool m_freeRun; MsgConfigureScopeVisNG(uint32_t traceSize, uint32_t timeBase, uint32_t timeOfsProMill, uint32_t triggerPre, bool freeRun) : m_traceSize(traceSize), m_timeBase(timeBase), m_timeOfsProMill(timeOfsProMill), m_triggerPre(triggerPre), m_freeRun(freeRun) {} }; // --------------------------------------------- class MsgScopeVisNGAddTrigger : public Message { MESSAGE_CLASS_DECLARATION public: static MsgScopeVisNGAddTrigger* create( const TriggerData& triggerData) { return new MsgScopeVisNGAddTrigger(triggerData); } const TriggerData& getTriggerData() const { return m_triggerData; } private: TriggerData m_triggerData; MsgScopeVisNGAddTrigger(const TriggerData& triggerData) : m_triggerData(triggerData) {} }; // --------------------------------------------- class MsgScopeVisNGChangeTrigger : public Message { MESSAGE_CLASS_DECLARATION public: static MsgScopeVisNGChangeTrigger* create( const TriggerData& triggerData, uint32_t triggerIndex) { return new MsgScopeVisNGChangeTrigger(triggerData, triggerIndex); } const TriggerData& getTriggerData() const { return m_triggerData; } uint32_t getTriggerIndex() const { return m_triggerIndex; } private: TriggerData m_triggerData; uint32_t m_triggerIndex; MsgScopeVisNGChangeTrigger(const TriggerData& triggerData, uint32_t triggerIndex) : m_triggerData(triggerData), m_triggerIndex(triggerIndex) {} }; // --------------------------------------------- class MsgScopeVisNGRemoveTrigger : public Message { MESSAGE_CLASS_DECLARATION public: static MsgScopeVisNGRemoveTrigger* create( uint32_t triggerIndex) { return new MsgScopeVisNGRemoveTrigger(triggerIndex); } uint32_t getTriggerIndex() const { return m_triggerIndex; } private: uint32_t m_triggerIndex; MsgScopeVisNGRemoveTrigger(uint32_t triggerIndex) : m_triggerIndex(triggerIndex) {} }; // --------------------------------------------- class MsgScopeVisNGMoveTrigger : public Message { MESSAGE_CLASS_DECLARATION public: static MsgScopeVisNGMoveTrigger* create( uint32_t triggerIndex, bool moveUpElseDown) { return new MsgScopeVisNGMoveTrigger(triggerIndex, moveUpElseDown); } uint32_t getTriggerIndex() const { return m_triggerIndex; } bool getMoveUp() const { return m_moveUpElseDown; } private: uint32_t m_triggerIndex; bool m_moveUpElseDown; MsgScopeVisNGMoveTrigger(uint32_t triggerIndex, bool moveUpElseDown) : m_triggerIndex(triggerIndex), m_moveUpElseDown(moveUpElseDown) {} }; // --------------------------------------------- class MsgScopeVisNGFocusOnTrigger : public Message { MESSAGE_CLASS_DECLARATION public: static MsgScopeVisNGFocusOnTrigger* create( uint32_t triggerIndex) { return new MsgScopeVisNGFocusOnTrigger(triggerIndex); } uint32_t getTriggerIndex() const { return m_triggerIndex; } private: uint32_t m_triggerIndex; MsgScopeVisNGFocusOnTrigger(uint32_t triggerIndex) : m_triggerIndex(triggerIndex) {} }; // --------------------------------------------- class MsgScopeVisNGAddTrace : public Message { MESSAGE_CLASS_DECLARATION public: static MsgScopeVisNGAddTrace* create( const TraceData& traceData) { return new MsgScopeVisNGAddTrace(traceData); } const TraceData& getTraceData() const { return m_traceData; } private: TraceData m_traceData; MsgScopeVisNGAddTrace(const TraceData& traceData) : m_traceData(traceData) {} }; // --------------------------------------------- class MsgScopeVisNGChangeTrace : public Message { MESSAGE_CLASS_DECLARATION public: static MsgScopeVisNGChangeTrace* create( const TraceData& traceData, uint32_t traceIndex) { return new MsgScopeVisNGChangeTrace(traceData, traceIndex); } const TraceData& getTraceData() const { return m_traceData; } uint32_t getTraceIndex() const { return m_traceIndex; } private: TraceData m_traceData; uint32_t m_traceIndex; MsgScopeVisNGChangeTrace(TraceData traceData, uint32_t traceIndex) : m_traceData(traceData), m_traceIndex(traceIndex) {} }; // --------------------------------------------- class MsgScopeVisNGRemoveTrace : public Message { MESSAGE_CLASS_DECLARATION public: static MsgScopeVisNGRemoveTrace* create( uint32_t traceIndex) { return new MsgScopeVisNGRemoveTrace(traceIndex); } uint32_t getTraceIndex() const { return m_traceIndex; } private: uint32_t m_traceIndex; MsgScopeVisNGRemoveTrace(uint32_t traceIndex) : m_traceIndex(traceIndex) {} }; // --------------------------------------------- class MsgScopeVisNGMoveTrace : public Message { MESSAGE_CLASS_DECLARATION public: static MsgScopeVisNGMoveTrace* create( uint32_t traceIndex, bool moveUpElseDown) { return new MsgScopeVisNGMoveTrace(traceIndex, moveUpElseDown); } uint32_t getTraceIndex() const { return m_traceIndex; } bool getMoveUp() const { return m_moveUpElseDown; } private: uint32_t m_traceIndex; bool m_moveUpElseDown; MsgScopeVisNGMoveTrace(uint32_t traceIndex, bool moveUpElseDown) : m_traceIndex(traceIndex), m_moveUpElseDown(moveUpElseDown) {} }; // --------------------------------------------- class MsgScopeVisNGFocusOnTrace : public Message { MESSAGE_CLASS_DECLARATION public: static MsgScopeVisNGFocusOnTrace* create( uint32_t traceIndex) { return new MsgScopeVisNGFocusOnTrace(traceIndex); } uint32_t getTraceIndex() const { return m_traceIndex; } private: uint32_t m_traceIndex; MsgScopeVisNGFocusOnTrace(uint32_t traceIndex) : m_traceIndex(traceIndex) {} }; // --------------------------------------------- class MsgScopeVisNGOneShot : public Message { MESSAGE_CLASS_DECLARATION public: static MsgScopeVisNGOneShot* create( bool oneShot) { return new MsgScopeVisNGOneShot(oneShot); } bool getOneShot() const { return m_oneShot; } private: bool m_oneShot; MsgScopeVisNGOneShot(bool oneShot) : m_oneShot(oneShot) {} }; // --------------------------------------------- class MsgScopeVisNGMemoryTrace : public Message { MESSAGE_CLASS_DECLARATION public: static MsgScopeVisNGMemoryTrace* create( uint32_t memoryIndex) { return new MsgScopeVisNGMemoryTrace(memoryIndex); } uint32_t getMemoryIndex() const { return m_memoryIndex; } private: uint32_t m_memoryIndex; MsgScopeVisNGMemoryTrace(uint32_t memoryIndex) : m_memoryIndex(memoryIndex) {} }; // --------------------------------------------- /** * Projection stuff */ class Projector { public: Projector(ProjectionType projectionType) : m_projectionType(projectionType), m_prevArg(0.0f), m_cache(0), m_cacheMaster(true) {} ~Projector() {} ProjectionType getProjectionType() const { return m_projectionType; } void settProjectionType(ProjectionType projectionType) { m_projectionType = projectionType; } void setCache(Real *cache) { m_cache = cache; } void setCacheMaster(bool cacheMaster) { m_cacheMaster = cacheMaster; } Real run(const Sample& s) { Real v; if ((m_cache) && !m_cacheMaster) { return m_cache[(int) m_projectionType]; } else { switch (m_projectionType) { case ProjectionImag: v = s.m_imag / SDR_RX_SCALEF; break; case ProjectionMagLin: { Real re = s.m_real / SDR_RX_SCALEF; Real im = s.m_imag / SDR_RX_SCALEF; Real magsq = re*re + im*im; v = std::sqrt(magsq); } break; case ProjectionMagDB: { Real re = s.m_real / SDR_RX_SCALEF; Real im = s.m_imag / SDR_RX_SCALEF; Real magsq = re*re + im*im; v = log10f(magsq) * 10.0f; } break; case ProjectionPhase: v = std::atan2((float) s.m_imag, (float) s.m_real) / M_PI; break; case ProjectionDPhase: { Real curArg = std::atan2((float) s.m_imag, (float) s.m_real); Real dPhi = (curArg - m_prevArg) / M_PI; m_prevArg = curArg; if (dPhi < -1.0f) { dPhi += 2.0f; } else if (dPhi > 1.0f) { dPhi -= 2.0f; } v = dPhi; } break; case ProjectionReal: default: v = s.m_real / SDR_RX_SCALEF; break; } if (m_cache) { m_cache[(int) m_projectionType] = v; } return v; } } private: ProjectionType m_projectionType; Real m_prevArg; Real *m_cache; bool m_cacheMaster; }; /** * Trigger stuff */ enum TriggerState { TriggerUntriggered, //!< Trigger is not kicked off yet (or trigger list is empty) TriggerTriggered, //!< Trigger has been kicked off TriggerDelay, //!< Trigger conditions have been kicked off but it is waiting for delay before final kick off TriggerNewConfig, //!< Special condition when a new configuration has been received }; struct TriggerCondition { public: Projector m_projector; TriggerData m_triggerData; //!< Trigger data bool m_prevCondition; //!< Condition (above threshold) at previous sample uint32_t m_triggerDelayCount; //!< Counter of samples for delay uint32_t m_triggerCounter; //!< Counter of trigger occurences TriggerCondition(const TriggerData& triggerData) : m_projector(ProjectionReal), m_triggerData(triggerData), m_prevCondition(false), m_triggerDelayCount(0), m_triggerCounter(0) { } ~TriggerCondition() { } void initProjector() { m_projector.settProjectionType(m_triggerData.m_projectionType); } void releaseProjector() { } void setData(const TriggerData& triggerData) { m_triggerData = triggerData; if (m_projector.getProjectionType() != m_triggerData.m_projectionType) { m_projector.settProjectionType(m_triggerData.m_projectionType); } m_prevCondition = false; m_triggerDelayCount = 0; m_triggerCounter = 0; } void operator=(const TriggerCondition& other) { setData(other.m_triggerData); } }; /** * Complex trace stuff */ typedef DoubleBufferSimple TraceBuffer; struct TraceBackBuffer { TraceBuffer m_traceBuffer; SampleVector::iterator m_endPoint; TraceBackBuffer() { m_endPoint = m_traceBuffer.getCurrent(); } void resize(uint32_t size) { m_traceBuffer.resize(size); } void reset() { m_traceBuffer.reset(); } void write(const SampleVector::const_iterator begin, const SampleVector::const_iterator end) { m_traceBuffer.write(begin, end); } unsigned int absoluteFill() const { return m_traceBuffer.absoluteFill(); } SampleVector::iterator current() { return m_traceBuffer.getCurrent(); } }; struct TraceBackDiscreteMemory { std::vector m_traceBackBuffers; uint32_t m_memSize; uint32_t m_currentMemIndex; uint32_t m_traceSize; /** * Give memory size in number of traces */ TraceBackDiscreteMemory(uint32_t size) : m_memSize(size), m_currentMemIndex(0), m_traceSize(0) { m_traceBackBuffers.resize(m_memSize); } /** * Resize all trace buffers in memory */ void resize(uint32_t size) { m_traceSize = size; for (std::vector::iterator it = m_traceBackBuffers.begin(); it != m_traceBackBuffers.end(); ++it) { it->resize(4*m_traceSize); } } /** * Move index forward by one position and return reference to the trace at this position * Copy a trace length of samples into the new memory slot */ TraceBackBuffer &store() { uint32_t nextMemIndex = m_currentMemIndex < (m_memSize-1) ? m_currentMemIndex+1 : 0; m_traceBackBuffers[nextMemIndex].reset(); m_traceBackBuffers[nextMemIndex].write(m_traceBackBuffers[m_currentMemIndex].m_endPoint - m_traceSize, m_traceBackBuffers[m_currentMemIndex].m_endPoint); m_currentMemIndex = nextMemIndex; return m_traceBackBuffers[m_currentMemIndex]; // new trace } /** * Recalls trace at shift positions back. Therefore 0 is current. Wraps around memory size. */ TraceBackBuffer& recall(uint32_t shift) { int index = (m_currentMemIndex + (m_memSize - (shift % m_memSize))) % m_memSize; return m_traceBackBuffers[index]; } /** * Return trace at current memory position */ TraceBackBuffer& current() { return m_traceBackBuffers[m_currentMemIndex]; } /** * Return trace at given memory position */ TraceBackBuffer& at(int index) { return m_traceBackBuffers[index]; } /** * Return current memory index */ uint32_t currentIndex() const { return m_currentMemIndex; } }; /** * Displayable trace stuff */ struct TraceControl { Projector m_projector; //!< Projector transform from complex trace to real (displayable) trace uint32_t m_traceCount[2]; //!< Count of samples processed (double buffered) Real m_maxPow; //!< Maximum power over the current trace for MagDB overlay display Real m_sumPow; //!< Cumulative power over the current trace for MagDB overlay display int m_nbPow; //!< Number of power samples over the current trace for MagDB overlay display TraceControl() : m_projector(ProjectionReal) { reset(); } ~TraceControl() { } void initProjector(ProjectionType projectionType) { m_projector.settProjectionType(projectionType); } void releaseProjector() { } void reset() { m_traceCount[0] = 0; m_traceCount[1] = 0; m_maxPow = 0.0f; m_sumPow = 0.0f; m_nbPow = 0; } }; struct Traces { std::vector m_tracesControl; //!< Corresponding traces control data std::vector m_tracesData; //!< Corresponding traces data std::vector m_traces[2]; //!< Double buffer of traces processed by glScope int m_traceSize; //!< Current size of a trace in buffer int m_maxTraceSize; //!< Maximum Size of a trace in buffer bool evenOddIndex; //!< Even (true) or odd (false) index Traces() : m_traceSize(0), m_maxTraceSize(0), evenOddIndex(true), m_x0(0), m_x1(0) { } ~Traces() { if (m_x0) delete[] m_x0; if (m_x1) delete[] m_x1; m_maxTraceSize = 0; } bool isVerticalDisplayChange(const TraceData& traceData, uint32_t traceIndex) { return (m_tracesData[traceIndex].m_projectionType != traceData.m_projectionType) || (m_tracesData[traceIndex].m_amp != traceData.m_amp) || (m_tracesData[traceIndex].m_ofs != traceData.m_ofs || (m_tracesData[traceIndex].m_traceColor != traceData.m_traceColor)); } void addTrace(const TraceData& traceData, int traceSize) { if (m_traces[0].size() < m_maxNbTraces) { m_traces[0].push_back(0); m_traces[1].push_back(0); m_tracesData.push_back(traceData); m_tracesControl.push_back(TraceControl()); m_tracesControl.back().initProjector(traceData.m_projectionType); resize(traceSize); } } void changeTrace(const TraceData& traceData, uint32_t traceIndex) { if (traceIndex < m_tracesControl.size()) { m_tracesControl[traceIndex].releaseProjector(); m_tracesControl[traceIndex].initProjector(traceData.m_projectionType); m_tracesData[traceIndex] = traceData; } } void removeTrace(uint32_t traceIndex) { if (traceIndex < m_tracesControl.size()) { m_traces[0].erase(m_traces[0].begin() + traceIndex); m_traces[1].erase(m_traces[1].begin() + traceIndex); m_tracesControl[traceIndex].releaseProjector(); m_tracesControl.erase(m_tracesControl.begin() + traceIndex); m_tracesData.erase(m_tracesData.begin() + traceIndex); resize(m_traceSize); // reallocate pointers } } void moveTrace(uint32_t traceIndex, bool upElseDown) { if ((!upElseDown) && (traceIndex == 0)) { return; } int nextControlIndex = (traceIndex + (upElseDown ? 1 : -1)) % (m_tracesControl.size()); int nextDataIndex = (traceIndex + (upElseDown ? 1 : -1)) % (m_tracesData.size()); // should be the same m_tracesControl[traceIndex].releaseProjector(); m_tracesControl[nextControlIndex].releaseProjector(); TraceControl nextControl = m_tracesControl[nextControlIndex]; m_tracesControl[nextControlIndex] = m_tracesControl[traceIndex]; m_tracesControl[traceIndex] = nextControl; TraceData nextData = m_tracesData[nextDataIndex]; m_tracesData[nextDataIndex] = m_tracesData[traceIndex]; m_tracesData[traceIndex] = nextData; m_tracesControl[traceIndex].initProjector(m_tracesData[traceIndex].m_projectionType); m_tracesControl[nextControlIndex].initProjector(m_tracesData[nextDataIndex].m_projectionType); } void resize(int traceSize) { m_traceSize = traceSize; if (m_traceSize > m_maxTraceSize) { delete[] m_x0; delete[] m_x1; m_x0 = new float[2*m_traceSize*m_maxNbTraces]; m_x1 = new float[2*m_traceSize*m_maxNbTraces]; m_maxTraceSize = m_traceSize; } std::fill_n(m_x0, 2*m_traceSize*m_traces[0].size(), 0.0f); std::fill_n(m_x1, 2*m_traceSize*m_traces[0].size(), 0.0f); for (unsigned int i = 0; i < m_traces[0].size(); i++) { (m_traces[0])[i] = &m_x0[2*m_traceSize*i]; (m_traces[1])[i] = &m_x1[2*m_traceSize*i]; } } uint32_t currentBufferIndex() const { return evenOddIndex? 0 : 1; } uint32_t size() const { return m_tracesControl.size(); } void switchBuffer() { evenOddIndex = !evenOddIndex; for (std::vector::iterator it = m_tracesControl.begin(); it != m_tracesControl.end(); ++it) { it->m_traceCount[currentBufferIndex()] = 0; } } private: float *m_x0; float *m_x1; }; class TriggerComparator { public: TriggerComparator() : m_level(0), m_reset(true) { computeLevels(); } bool triggered(const Sample& s, TriggerCondition& triggerCondition) { if (triggerCondition.m_triggerData.m_triggerLevel != m_level) { m_level = triggerCondition.m_triggerData.m_triggerLevel; computeLevels(); } bool condition, trigger; if (triggerCondition.m_projector.getProjectionType() == ProjectionMagDB) { condition = triggerCondition.m_projector.run(s) > m_levelPowerDB; } else if (triggerCondition.m_projector.getProjectionType() == ProjectionMagLin) { condition = triggerCondition.m_projector.run(s) > m_levelPowerLin; } else { condition = triggerCondition.m_projector.run(s) > m_level; } if (m_reset) { triggerCondition.m_prevCondition = condition; m_reset = false; return false; } if (triggerCondition.m_triggerData.m_triggerBothEdges) { trigger = triggerCondition.m_prevCondition ? !condition : condition; // This is a XOR between bools } else if (triggerCondition.m_triggerData.m_triggerPositiveEdge) { trigger = !triggerCondition.m_prevCondition && condition; } else { trigger = triggerCondition.m_prevCondition && !condition; } // if (trigger) { // qDebug("ScopeVisNG::triggered: %s/%s %f/%f", // triggerCondition.m_prevCondition ? "T" : "F", // condition ? "T" : "F", // triggerCondition.m_projector->run(s), // triggerCondition.m_triggerData.m_triggerLevel); // } triggerCondition.m_prevCondition = condition; return trigger; } void reset() { m_reset = true; } private: void computeLevels() { m_levelPowerLin = m_level + 1.0f; m_levelPowerDB = (100.0f * (m_level - 1.0f)); } Real m_level; Real m_levelPowerDB; Real m_levelPowerLin; bool m_reset; }; GLScopeNG* m_glScope; uint32_t m_preTriggerDelay; //!< Pre-trigger delay in number of samples std::vector m_triggerConditions; //!< Chain of triggers uint32_t m_currentTriggerIndex; //!< Index of current index in the chain uint32_t m_focusedTriggerIndex; //!< Index of the trigger that has focus TriggerState m_triggerState; //!< Current trigger state Traces m_traces; //!< Displayable traces int m_focusedTraceIndex; //!< Index of the trace that has focus uint32_t m_traceSize; //!< Size of traces in number of samples int m_nbSamples; //!< Number of samples yet to process in one complex trace uint32_t m_timeBase; //!< Trace display time divisor uint32_t m_timeOfsProMill; //!< Start trace shift in 1/1000 trace size bool m_traceStart; //!< Trace is at start point int m_traceFill; //!< Count of samples accumulated into trace int m_zTraceIndex; //!< Index of the trace used for Z input (luminance or false colors) SampleVector::const_iterator m_triggerPoint; //!< Trigger start location in the samples vector int m_sampleRate; TraceBackDiscreteMemory m_traceDiscreteMemory; //!< Complex trace memory for triggered states TODO: vectorize when more than on input is allowed bool m_freeRun; //!< True if free running (trigger globally disabled) int m_maxTraceDelay; //!< Maximum trace delay TriggerComparator m_triggerComparator; //!< Compares sample level to trigger level QMutex m_mutex; Real m_projectorCache[(int) nbProjectionTypes]; bool m_triggerOneShot; //!< True when one shot mode is active bool m_triggerWaitForReset; //!< In one shot mode suspended until reset by UI uint32_t m_currentTraceMemoryIndex; //!< The current index of trace in memory (0: current) /** * Moves on to the next trigger if any or increments trigger count if in repeat mode * - If not final it returns true * - If final i.e. signal is actually triggerd it returns false */ bool nextTrigger(); //!< Returns true if not final /** * Process a sample trace which length is at most the trace length (m_traceSize) */ void processTrace(const SampleVector::const_iterator& begin, const SampleVector::const_iterator& end, int& triggerPointToEnd); /** * process a trace in memory at current trace index in memory */ void processMemoryTrace(); /** * Process traces from complex trace memory buffer. * - if finished it returns the number of unprocessed samples left in the buffer * - if not finished it returns -1 */ int processTraces(const SampleVector::const_iterator& begin, const SampleVector::const_iterator& end, bool traceBack = false); /** * Get maximum trace delay */ void updateMaxTraceDelay(); /** * Initialize trace buffers */ void initTraceBuffers(); /** * Calculate trigger levels on display * - every time a trigger condition focus changes TBD * - every time the focused trigger condition changes its projection type or level * - every time a trace data changes: projection type, amp, offset * - every time a trace data is added or removed */ void computeDisplayTriggerLevels(); /** * Update glScope display * - Live trace: call glScipe update method * - Trace in memory: call process memory trace */ void updateGLScopeDisplay(); }; #endif /* SDRBASE_DSP_SCOPEVISNG_H_ */