initial support for shuffle with early and late tick setup on 16PPQN calls

8 months ago · 6f0863f247
parent a89d0e70b9
commit 6f0863f247
2 changed files with 192 additions and 107 deletions
--- a/src/uClock.cpp
+++ b/src/uClock.cpp
@ -238,10 +238,43 @@ void uClockClass::tap()
    // tap me
 }
-// TODO: Shuffle stuff
+void uClockClass::setShuffle(bool active)
 void uClockClass::shuffle() 
 {
-    // shuffle me
+    ATOMIC(shuffle.active = active)
 }
 bool uClockClass::isShuffled()
 {
    return shuffle.active;
 }
 void uClockClass::setShuffleSize(uint8_t size)
 {
    if (size > MAX_SHUFFLE_TEMPLATE_SIZE)
        size = MAX_SHUFFLE_TEMPLATE_SIZE;
    ATOMIC(shuffle.size = size)
 }
 void uClockClass::setShuffleData(uint8_t step, int8_t tick)
 {
    if (step >= MAX_SHUFFLE_TEMPLATE_SIZE)
        return;
    ATOMIC(shuffle.step[step] = tick)
 }
 void uClockClass::setShuffleTemplate(int8_t * shuff, uint8_t size)
 {
    if (size > MAX_SHUFFLE_TEMPLATE_SIZE)
        size = MAX_SHUFFLE_TEMPLATE_SIZE;
    setShuffleSize(size);
    for (uint8_t i=0; i < size; i++) {
        setShuffleData(i, shuff[i]);
    }
 }
 int8_t uClockClass::getShuffleLength()
 {
    return shuffle_length_ctrl;
 }
 void uClockClass::handleExternalClock() 
@ -331,18 +364,17 @@ void uClockClass::handleTimerInt()
        onClock96PPQNCallback(internal_tick);
    }
-    if (mod6_counter == 0) {
+    // 16PPQN call and shuffle processing if enabled
-        if (onClock32PPQNCallback) {
+    if (processShuffle() == 0) {
            onClock32PPQNCallback(div32th_counter);
        }
        if (onClock16PPQNCallback) {
            onClock16PPQNCallback(div16th_counter);
        }
        div16th_counter++;
-        div32th_counter++;
+        shuffle_shoot_ctrl = false;
    }
-    if (mod6_counter == 3) {
+    // 32PPQN call. does anyone uses it?
    if (mod6_counter == 3 || mod6_counter == 6) {
        if (onClock32PPQNCallback) {
            onClock32PPQNCallback(div32th_counter);
        }
@ -356,7 +388,35 @@ void uClockClass::handleTimerInt()
    if (mod6_counter == 6) {
        mod6_counter = 0;
    }
-    
+}
 uint8_t inline uClockClass::processShuffle()
 {
    uint8_t mod6_shuffle_counter;
    if (!shuffle.active) {
        mod6_shuffle_counter = mod6_counter;
    } else {
        // apply shuffle template to step
        int8_t shff = shuffle.step[div16th_counter%shuffle.size];
        // keep track of next note shuffle for current note lenght control
        shuffle_length_ctrl = shuffle.step[(div16th_counter+1)%shuffle.size];
        // prepare the next mod6 quantize to be called
        if (shff == 0) {
            mod6_shuffle_counter = mod6_counter;
            shuffle_length_ctrl += shff;
        } else if (shff > 0) {
            if (shuffle_shoot_ctrl == false && mod6_counter > shff) 
                shuffle_shoot_ctrl = true;
            mod6_shuffle_counter = shuffle_shoot_ctrl ? mod6_counter - shff : 1;
            shuffle_length_ctrl -= shff;
        } else if (shff < 0) {
            if (shuffle_shoot_ctrl == false && mod6_counter == 0) 
                shuffle_shoot_ctrl = true;
            mod6_shuffle_counter = shff - mod6_counter == -6 ? shuffle_shoot_ctrl ? 0 : 1 : 1;
            shuffle_length_ctrl += shff;
        }
    }
    return mod6_shuffle_counter;
 }
 // elapsed time support
--- a/src/uClock.h
+++ b/src/uClock.h
@ -34,6 +34,16 @@
 namespace umodular { namespace clock {
 // min: 2 step, max: 16 steps  
 // adjust the size of you template if more than 16 needed
 // step adjust goes min: -5, max: 5
 #define MAX_SHUFFLE_TEMPLATE_SIZE   16
 typedef struct {
    bool active;
    uint8_t size = MAX_SHUFFLE_TEMPLATE_SIZE;
    int8_t step[MAX_SHUFFLE_TEMPLATE_SIZE] = {0};
 } SHUFFLE_TEMPLATE;
 // for smooth slave tempo calculate display you should raise this value 
 // in between 64 to 128.
 // note: this doesn't impact on sync time, only display time getTempo()
@ -51,105 +61,120 @@ namespace umodular { namespace clock {
 #define SECS_PER_DAY  (SECS_PER_HOUR * 24L)
 class uClockClass {
 private:
    float inline freqToBpm(uint32_t freq);
    // shuffle
    uint8_t inline processShuffle();
    void (*onClock96PPQNCallback)(uint32_t tick);
    void (*onClock32PPQNCallback)(uint32_t tick);
    void (*onClock16PPQNCallback)(uint32_t tick);
    void (*onClockStartCallback)();
    void (*onClockStopCallback)();
    // internal clock control
    uint32_t internal_tick;
    uint32_t div32th_counter;
    uint32_t div16th_counter;
    uint8_t mod6_counter;
    // external clock control
    volatile uint32_t external_clock;
    volatile uint32_t external_tick;
    volatile uint32_t indiv32th_counter;
    volatile uint32_t indiv16th_counter;
    volatile uint8_t inmod6_counter;
    volatile uint32_t interval;
    uint32_t last_interval;
    uint32_t sync_interval;
    float tempo;
    uint32_t start_timer;
    uint8_t mode;
    volatile uint32_t ext_interval_buffer[EXT_INTERVAL_BUFFER_SIZE];
    uint16_t ext_interval_idx;
    // shuffle implementation that applies to 16PPQN callback
    volatile SHUFFLE_TEMPLATE shuffle;
    bool shuffle_shoot_ctrl = true;
    volatile int8_t shuffle_length_ctrl = 0;
 public:
    enum {
        INTERNAL_CLOCK = 0,
        EXTERNAL_CLOCK
    };
    enum {
        PAUSED = 0,
        STARTING,
        STARTED
    };
    uint8_t state;
    uClockClass();
-    private:
+    void setClock96PPQNOutput(void (*callback)(uint32_t tick)) {
-        
+        onClock96PPQNCallback = callback;
-        float inline freqToBpm(uint32_t freq);
+    }
-
+    
-        void (*onClock96PPQNCallback)(uint32_t tick);
+    void setClock32PPQNOutput(void (*callback)(uint32_t tick)) {
-        void (*onClock32PPQNCallback)(uint32_t tick);
+        onClock32PPQNCallback = callback;
-        void (*onClock16PPQNCallback)(uint32_t tick);
+    }
-        void (*onClockStartCallback)();
+
-        void (*onClockStopCallback)();
+    void setClock16PPQNOutput(void (*callback)(uint32_t tick)) {
-
+        onClock16PPQNCallback = callback;
-        // internal clock control
+    }
-        uint32_t internal_tick;
+
-        uint32_t div32th_counter;
+    void setOnClockStartOutput(void (*callback)()) {
-        uint32_t div16th_counter;
+        onClockStartCallback = callback;
-        uint8_t mod6_counter;
+    }
-
+
-        // external clock control
+    void setOnClockStopOutput(void (*callback)()) {
-        volatile uint32_t external_clock;
+        onClockStopCallback = callback;
-        volatile uint32_t external_tick;
+    }
-        volatile uint32_t indiv32th_counter;
+
-        volatile uint32_t indiv16th_counter;
+    void init();
-        volatile uint8_t inmod6_counter;
+    void handleTimerInt();
-        volatile uint32_t interval;
+    void handleExternalClock();
-        uint32_t last_interval;
+    void resetCounters();
-        uint32_t sync_interval;
+    
-
+    // external class control
-        float tempo;
+    void start();
-        uint32_t start_timer;
+    void stop();
-        uint8_t mode;
+    void pause();
    void setTempo(float bpm);
    float getTempo();
    // external timming control
    void setMode(uint8_t tempo_mode);
    uint8_t getMode();
    void clockMe();
    // shuffle
    void setShuffle(bool active);
    bool isShuffled();
    void setShuffleSize(uint8_t size);
    void setShuffleData(uint8_t step, int8_t tick);
    void setShuffleTemplate(int8_t * shuff, uint8_t size);
    // use this to know how many positive or negative ticks to add to current note length
    int8_t getShuffleLength();
    // todo!
    void tap();
-        volatile uint32_t ext_interval_buffer[EXT_INTERVAL_BUFFER_SIZE];
+    // elapsed time support
-        uint16_t ext_interval_idx;
+    uint8_t getNumberOfSeconds(uint32_t time);
-
+    uint8_t getNumberOfMinutes(uint32_t time);
-    public:
+    uint8_t getNumberOfHours(uint32_t time);
-
+    uint8_t getNumberOfDays(uint32_t time);
-        enum {
+    uint32_t getNowTimer();
-            INTERNAL_CLOCK = 0,
+    uint32_t getPlayTime();
            EXTERNAL_CLOCK
        };
        enum {
            PAUSED = 0,
            STARTING,
            STARTED
        };
        uint8_t state;
        uClockClass();
        void setClock96PPQNOutput(void (*callback)(uint32_t tick)) {
            onClock96PPQNCallback = callback;
        }
        void setClock32PPQNOutput(void (*callback)(uint32_t tick)) {
            onClock32PPQNCallback = callback;
        }
        void setClock16PPQNOutput(void (*callback)(uint32_t tick)) {
            onClock16PPQNCallback = callback;
        }
        void setOnClockStartOutput(void (*callback)()) {
            onClockStartCallback = callback;
        }
        void setOnClockStopOutput(void (*callback)()) {
            onClockStopCallback = callback;
        }
        void init();
        void handleTimerInt();
        void handleExternalClock();
        void resetCounters();
        // external class control
        void start();
        void stop();
        void pause();
        void setTempo(float bpm);
        float getTempo();
        // external timming control
        void setMode(uint8_t tempo_mode);
        uint8_t getMode();
        void clockMe();
        // todo!
        void shuffle();
        void tap();
        // elapsed time support
        uint8_t getNumberOfSeconds(uint32_t time);
        uint8_t getNumberOfMinutes(uint32_t time);
        uint8_t getNumberOfHours(uint32_t time);
        uint8_t getNumberOfDays(uint32_t time);
        uint32_t getNowTimer();
        uint32_t getPlayTime();
 };
 } } // end namespace umodular::clock