/*
 ____  _____ _        _    
| __ )| ____| |      / \   
|  _ \|  _| | |     / _ \  
| |_) | |___| |___ / ___ \ 
|____/|_____|_____/_/   \_\

The platform for ultra-low latency audio and sensor processing

http://bela.io

A project of the Augmented Instruments Laboratory within the
Centre for Digital Music at Queen Mary University of London.
http://www.eecs.qmul.ac.uk/~andrewm

(c) 2016 Augmented Instruments Laboratory: Andrew McPherson,
	Astrid Bin, Liam Donovan, Christian Heinrichs, Robert Jack,
	Giulio Moro, Laurel Pardue, Victor Zappi. All rights reserved.

The Bela software is distributed under the GNU Lesser General Public License
(LGPL 3.0), available here: https://www.gnu.org/licenses/lgpl-3.0.txt
*/

/*
 *	USING A CUSTOM RENDER.CPP FILE FOR PUREDATA PATCHES - HEAVY
 *  ===========================================================
 *  ||                                                       ||
 *  || OPEN THE ENCLOSED _main.pd PATCH FOR MORE INFORMATION ||
 *  || ----------------------------------------------------- ||
 *  ===========================================================
 */

#include <Bela.h>
#include <Midi.h>
#include <Scope.h>
#include <cmath>
#include <Heavy_bela.h>
#include <string.h>
#include <stdlib.h>
#include <string.h>
#include <DigitalChannelManager.h>

/*
 *  MODIFICATION
 *  ------------
 *  Global variables for tremolo effect applied to libpd output
 */

float gTremoloRate = 4.0;
float gPhase;

/*********/

/*
 *	HEAVY CONTEXT & BUFFERS
 */

Hv_bela *gHeavyContext;
float *gHvInputBuffers = NULL, *gHvOutputBuffers = NULL;
unsigned int gHvInputChannels = 0, gHvOutputChannels = 0;

float gInverseSampleRate;

/*
 *	HEAVY FUNCTIONS
 */

// TODO: rename this
#define LIBPD_DIGITAL_OFFSET 11 // digitals are preceded by 2 audio and 8 analogs (even if using a different number of analogs)

void printHook(double timestampSecs, const char *printLabel, const char *msgString, void *userData) {
  rt_printf("Message from Heavy patch: [@ %.3f] %s: %s\n", timestampSecs, printLabel, msgString);
}


// digitals
static DigitalChannelManager dcm;

void sendDigitalMessage(bool state, unsigned int delay, void* receiverName){
	hv_sendFloatToReceiver(gHeavyContext, hv_stringToHash((char*)receiverName), (float)state);
//	rt_printf("%s: %d\n", (char*)receiverName, state);
}

// TODO: turn them into hv hashes and adjust sendDigitalMessage accordingly
char hvDigitalInHashes[16][21]={
	{"bela_digitalIn11"},{"bela_digitalIn12"},{"bela_digitalIn13"},{"bela_digitalIn14"},{"bela_digitalIn15"},
	{"bela_digitalIn16"},{"bela_digitalIn17"},{"bela_digitalIn18"},{"bela_digitalIn19"},{"bela_digitalIn20"},
	{"bela_digitalIn21"},{"bela_digitalIn22"},{"bela_digitalIn23"},{"bela_digitalIn24"},{"bela_digitalIn25"},
	{"bela_digitalIn26"}
};

static void sendHook(
	double timestamp, // in milliseconds
	const char *receiverName,
	const HvMessage *const m,
	void *userData) {

	/*
	 *  MODIFICATION
 	 *  ------------
	 *  Parse float sent to receiver 'tremoloRate' and assign it to a global variable
	 */

	if(strncmp(receiverName, "tremoloRate", 11) == 0){
		float value = hv_msg_getFloat(m, 0); // see the Heavy C API documentation: https://enzienaudio.com/docs/index.html#8.c
		gTremoloRate = value;
	}

	/*********/

	// Bela digital
	
	// Bela digital run-time messages

	// TODO: this first block is almost an exact copy of libpd's code, should we add this to the class?
	// let's make this as optimized as possible for built-in digital Out parsing
	// the built-in digital receivers are of the form "bela_digitalOutXX" where XX is between 11 and 26
	static int prefixLength = 15; // strlen("bela_digitalOut")
	if(strncmp(receiverName, "bela_digitalOut", prefixLength)==0){
		if(receiverName[prefixLength] != 0){ //the two ifs are used instead of if(strlen(source) >= prefixLength+2)
			if(receiverName[prefixLength + 1] != 0){
				// quickly convert the suffix to integer, assuming they are numbers, avoiding to call atoi
				int receiver = ((receiverName[prefixLength] - 48) * 10);
				receiver += (receiverName[prefixLength+1] - 48);
				unsigned int channel = receiver - LIBPD_DIGITAL_OFFSET; // go back to the actual Bela digital channel number
				bool value = hv_msg_getFloat(m, 0);
				if(channel < 16){ //16 is the hardcoded value for the number of digital channels
					dcm.setValue(channel, value);
				}
			}
		}
	}

	// Bela digital initialization messages
	if(strcmp(receiverName, "bela_setDigital") == 0){
		// Third argument (optional) can be ~ or sig for signal-rate, message-rate otherwise.
		// [in 14 ~(
		// |
		// [s bela_setDigital]
		// is signal("sig" or "~") or message("message", default) rate
		bool isMessageRate = true; // defaults to message rate
		bool direction = 0; // initialize it just to avoid the compiler's warning
		bool disable = false;
		int numArgs = hv_msg_getNumElements(m);
		if(numArgs < 2 || numArgs > 3 || !hv_msg_isSymbol(m, 0) || !hv_msg_isFloat(m, 1))
			return;
		if(numArgs == 3 && !hv_msg_isSymbol(m,2))
			return;
		char * symbol = hv_msg_getSymbol(m, 0);

		if(strcmp(symbol, "in") == 0){
			direction = INPUT;
		} else if(strcmp(symbol, "out") == 0){
			direction = OUTPUT;
		} else if(strcmp(symbol, "disable") == 0){
			disable = true;
		} else {
			return;
		}
		int channel = hv_msg_getFloat(m, 1) - LIBPD_DIGITAL_OFFSET;
		if(disable == true){
			dcm.unmanage(channel);
			return;
		}
		if(numArgs >= 3){
			char* s = hv_msg_getSymbol(m, 2);
			if(strcmp(s, "~") == 0  || strncmp(s, "sig", 3) == 0){
				isMessageRate = false;
			}
		}
		dcm.manage(channel, direction, isMessageRate);
	}
}


/*
 * SETUP, RENDER LOOP & CLEANUP
 */

// leaving this here, trying to come up with a coherent interface with libpd.
// commenting them out so the compiler does not warn
// 2 audio + (up to)8 analog + (up to) 16 digital + 4 scope outputs
//static const unsigned int gChannelsInUse = 30;
//static unsigned int gAnalogChannelsInUse = 8; // hard-coded for the moment, TODO: get it at run-time from hv_context
//static const unsigned int gFirstAudioChannel = 0;
//static const unsigned int gFirstAnalogChannel = 2;
static const unsigned int gFirstDigitalChannel = 10;
static const unsigned int gFirstScopeChannel = 26;
static unsigned int gDigitalSigInChannelsInUse;
static unsigned int gDigitalSigOutChannelsInUse;

// Bela Midi
Midi midi;
unsigned int hvMidiHashes[7];
// Bela Scope
Scope scope;
unsigned int gScopeChannelsInUse;
float* gScopeOut;


bool setup(BelaContext *context, void *userData)	{
	if(context->audioInChannels != context->audioOutChannels ||
			context->analogInChannels != context->analogOutChannels){
		// It should actually work, but let's test it before releasing it!
		printf("Error: TODO: a different number of channels for inputs and outputs is not yet supported\n");
		return false;
	}

	/*
	 *  MODIFICATION
 	 *  ------------
	 *  Initialise variables for tremolo effect
	 */

	gPhase = 0.0;

	/*********/

	/* HEAVY */
	hvMidiHashes[kmmNoteOn] = hv_stringToHash("__hv_notein");
//	hvMidiHashes[kmmNoteOff] = hv_stringToHash("noteoff"); // this is handled differently, see the render function
	hvMidiHashes[kmmControlChange] = hv_stringToHash("__hv_ctlin");
	// Note that the ones below are not defined by Heavy, but they are here for (wishing) forward-compatibility
	// You need to receive from the corresponding symbol in Pd and unpack the message, e.g.:
	//[r __hv_pgmin]
	//|
	//[unpack f f]
	//|   |
	//|   [print pgmin_channel]
	//[print pgmin_number]
	hvMidiHashes[kmmProgramChange] = hv_stringToHash("__hv_pgmin");
	hvMidiHashes[kmmPolyphonicKeyPressure] = hv_stringToHash("__hv_polytouchin");
	hvMidiHashes[kmmChannelPressure] = hv_stringToHash("__hv_touchin");
	hvMidiHashes[kmmPitchBend] = hv_stringToHash("__hv_bendin");

	gHeavyContext = hv_bela_new(context->audioSampleRate);

	gHvInputChannels = hv_getNumInputChannels(gHeavyContext);
	gHvOutputChannels = hv_getNumOutputChannels(gHeavyContext);

	gScopeChannelsInUse = gHvOutputChannels > gFirstScopeChannel ?
			gHvOutputChannels - gFirstScopeChannel : 0;
	gDigitalSigInChannelsInUse = gHvInputChannels > gFirstDigitalChannel ?
			gHvInputChannels - gFirstDigitalChannel : 0;
	gDigitalSigOutChannelsInUse = gHvOutputChannels > gFirstDigitalChannel ?
			gHvOutputChannels - gFirstDigitalChannel - gScopeChannelsInUse: 0;

	printf("Starting Heavy context with %d input channels and %d output channels\n",
			  gHvInputChannels, gHvOutputChannels);
	printf("Channels in use:\n");
	printf("Digital in : %u, Digital out: %u\n", gDigitalSigInChannelsInUse, gDigitalSigOutChannelsInUse);
	printf("Scope out: %u\n", gScopeChannelsInUse);

	if(gHvInputChannels != 0) {
		gHvInputBuffers = (float *)calloc(gHvInputChannels * context->audioFrames,sizeof(float));
	}
	if(gHvOutputChannels != 0) {
		gHvOutputBuffers = (float *)calloc(gHvOutputChannels * context->audioFrames,sizeof(float));
	}

	gInverseSampleRate = 1.0 / context->audioSampleRate;

	// Set heavy print hook
	hv_setPrintHook(gHeavyContext, printHook);
	// Set heavy send hook
	hv_setSendHook(gHeavyContext, sendHook);

	// TODO: change these hardcoded port values and actually change them in the Midi class
	midi.readFrom(0);
	midi.writeTo(0);
	midi.enableParser(true);

	if(gScopeChannelsInUse > 0){
		// block below copy/pasted from libpd, except
		scope.setup(gScopeChannelsInUse, context->audioSampleRate);
		gScopeOut = new float[gScopeChannelsInUse];
	}
	// Bela digital
	dcm.setCallback(sendDigitalMessage);
	if(context->digitalChannels > 0){
		for(unsigned int ch = 0; ch < context->digitalChannels; ++ch){
			dcm.setCallbackArgument(ch, hvDigitalInHashes[ch]);
		}
	}
	// unlike libpd, no need here to bind the bela_digitalOut.. receivers

	return true;
}


void render(BelaContext *context, void *userData)
{
	{
		int num;
		while((num = midi.getParser()->numAvailableMessages()) > 0){
			static MidiChannelMessage message;
			message = midi.getParser()->getNextChannelMessage();
			switch(message.getType()){
			case kmmNoteOn: {
				//message.prettyPrint();
				int noteNumber = message.getDataByte(0);
				int velocity = message.getDataByte(1);
				int channel = message.getChannel();
				// rt_printf("message: noteNumber: %f, velocity: %f, channel: %f\n", noteNumber, velocity, channel);
				hv_vscheduleMessageForReceiver(gHeavyContext, hvMidiHashes[kmmNoteOn], 0, "fff",
						(float)noteNumber, (float)velocity, (float)channel+1);
				break;
			}
			case kmmNoteOff: {
				/* PureData does not seem to handle noteoff messages as per the MIDI specs,
				 * so that the noteoff velocity is ignored. Here we convert them to noteon
				 * with a velocity of 0.
				 */
				int noteNumber = message.getDataByte(0);
				// int velocity = message.getDataByte(1); // would be ignored by Pd
				int channel = message.getChannel();
				// note we are sending the below to hvHashes[kmmNoteOn] !!
				hv_vscheduleMessageForReceiver(gHeavyContext, hvMidiHashes[kmmNoteOn], 0, "fff",
						(float)noteNumber, (float)0, (float)channel+1);
				break;
			}
			case kmmControlChange: {
				int channel = message.getChannel();
				int controller = message.getDataByte(0);
				int value = message.getDataByte(1);
				hv_vscheduleMessageForReceiver(gHeavyContext, hvMidiHashes[kmmControlChange], 0, "fff",
						(float)value, (float)controller, (float)channel+1);
				break;
			}
			case kmmProgramChange: {
				int channel = message.getChannel();
				int program = message.getDataByte(0);
				hv_vscheduleMessageForReceiver(gHeavyContext, hvMidiHashes[kmmProgramChange], 0, "ff",
						(float)program, (float)channel+1);
				break;
			}
			case kmmPolyphonicKeyPressure: {
				//TODO: untested, I do not have anything with polyTouch... who does, anyhow?
				int channel = message.getChannel();
				int pitch = message.getDataByte(0);
				int value = message.getDataByte(1);
				hv_vscheduleMessageForReceiver(gHeavyContext, hvMidiHashes[kmmPolyphonicKeyPressure], 0, "fff",
						(float)channel+1, (float)pitch, (float)value);
				break;
			}
			case kmmChannelPressure:
			{
				int channel = message.getChannel();
				int value = message.getDataByte(0);
				hv_vscheduleMessageForReceiver(gHeavyContext, hvMidiHashes[kmmChannelPressure], 0, "ff",
						(float)value, (float)channel+1);
				break;
			}
			case kmmPitchBend:
			{
				int channel = message.getChannel();
				int value = ((message.getDataByte(1) << 7) | message.getDataByte(0));
				hv_vscheduleMessageForReceiver(gHeavyContext, hvMidiHashes[kmmPitchBend], 0, "ff",
						(float)value, (float)channel+1);
				break;
			}
			case kmmNone:
			case kmmAny:
				break;
			}
		}
	}

	// De-interleave the data
	if(gHvInputBuffers != NULL) {
		for(unsigned int n = 0; n < context->audioFrames; n++) {
			for(unsigned int ch = 0; ch < gHvInputChannels; ch++) {
				if(ch >= context->audioInChannels+context->analogInChannels) {
					// THESE ARE PARAMETER INPUT 'CHANNELS' USED FOR ROUTING
					// 'sensor' outputs from routing channels of dac~ are passed through here
					break;
				} else {
					// If more than 2 ADC inputs are used in the pd patch, route the analog inputs
					// i.e. ADC3->analogIn0 etc. (first two are always audio inputs)
					if(ch >= context->audioInChannels)	{
						int m = n/2;
						float mIn = context->analogIn[m*context->analogInChannels + (ch-context->audioInChannels)];
						gHvInputBuffers[ch * context->audioFrames + n] = mIn;
					} else {
						gHvInputBuffers[ch * context->audioFrames + n] = context->audioIn[n * context->audioInChannels + ch];
					}
				}
			}
		}
	}

	// Bela digital in
	// note: in multiple places below we assume that the number of digital frames is same as number of audio
	// Bela digital in at message-rate
	dcm.processInput(context->digital, context->digitalFrames);

	// Bela digital in at signal-rate
	if(gDigitalSigInChannelsInUse > 0)
	{
		unsigned int j, k;
		float *p0, *p1;
		const unsigned int gLibpdBlockSize = context->audioFrames;
		const unsigned int  audioFrameBase = 0;
		float* gInBuf = gHvInputBuffers;
		// block below copy/pasted from libpd, except
		// 16 has been replaced with gDigitalSigInChannelsInUse
		for (j = 0, p0 = gInBuf; j < gLibpdBlockSize; j++, p0++) {
			unsigned int digitalFrame = audioFrameBase + j;
			for (k = 0, p1 = p0 + gLibpdBlockSize * gFirstDigitalChannel;
					k < gDigitalSigInChannelsInUse; ++k, p1 += gLibpdBlockSize) {
				if(dcm.isSignalRate(k) && dcm.isInput(k)){ // only process input channels that are handled at signal rate
					*p1 = digitalRead(context, digitalFrame, k);
				}
			}
		}
	}


	// replacement for bang~ object
	//hv_vscheduleMessageForReceiver(gHeavyContext, "bela_bang", 0.0f, "b");

	hv_bela_process_inline(gHeavyContext, gHvInputBuffers, gHvOutputBuffers, context->audioFrames);

	// Bela digital out
	// Bela digital out at signal-rate
	if(gDigitalSigOutChannelsInUse > 0)
	{
			unsigned int j, k;
			float *p0, *p1;
			const unsigned int gLibpdBlockSize = context->audioFrames;
			const unsigned int  audioFrameBase = 0;
			float* gOutBuf = gHvOutputBuffers;
			// block below copy/pasted from libpd, except
			// context->digitalChannels has been replaced with gDigitalSigOutChannelsInUse
			for (j = 0, p0 = gOutBuf; j < gLibpdBlockSize; ++j, ++p0) {
				unsigned int digitalFrame = (audioFrameBase + j);
				for (k = 0, p1 = p0  + gLibpdBlockSize * gFirstDigitalChannel;
						k < gDigitalSigOutChannelsInUse; k++, p1 += gLibpdBlockSize) {
					if(dcm.isSignalRate(k) && dcm.isOutput(k)){ // only process output channels that are handled at signal rate
						digitalWriteOnce(context, digitalFrame, k, *p1 > 0.5);
					}
				}
			}
	}
	// Bela digital out at message-rate
	dcm.processOutput(context->digital, context->digitalFrames);

	// Bela scope
	if(gScopeChannelsInUse > 0)
	{
		unsigned int j, k;
		float *p0, *p1;
		const unsigned int gLibpdBlockSize = context->audioFrames;
		float* gOutBuf = gHvOutputBuffers;

		// block below copy/pasted from libpd
		for (j = 0, p0 = gOutBuf; j < gLibpdBlockSize; ++j, ++p0) {
			for (k = 0, p1 = p0  + gLibpdBlockSize * gFirstScopeChannel; k < gScopeChannelsInUse; k++, p1 += gLibpdBlockSize) {
				gScopeOut[k] = *p1;
			}
			scope.log(gScopeOut);
		}
	}

	// Interleave the output data
	if(gHvOutputBuffers != NULL) {
		for(unsigned int n = 0; n < context->audioFrames; n++) {

			/*
			 *  MODIFICATION
				 *  ------------
			 *  Processing for tremolo effect while writing libpd output to Bela output buffer
			 */

			// Generate a sinewave with frequency set by gTremoloRate
			// and amplitude from -0.5 to 0.5
			float lfo = sinf(gPhase) * 0.5;
			// Keep track and wrap the phase of the sinewave
			gPhase += 2.0 * M_PI * gTremoloRate * gInverseSampleRate;
			if(gPhase > 2.0 * M_PI)
				gPhase -= 2.0 * M_PI;

			/*********/

			for(unsigned int ch = 0; ch < gHvOutputChannels; ch++) {
				if(ch <= context->audioOutChannels+context->analogOutChannels) {
					if(ch >= context->audioOutChannels)	{
						int m = n/2;
						context->analogOut[m * context->analogFrames + (ch-context->audioOutChannels)] = constrain(gHvOutputBuffers[ch*context->audioFrames + n],0.0,1.0);
					} else {
						context->audioOut[n * context->audioOutChannels + ch] = gHvOutputBuffers[ch * context->audioFrames + n] * lfo; // MODIFICATION (* lfo)
					}
				}
			}
		}
	}

}


void cleanup(BelaContext *context, void *userData)
{

	hv_bela_free(gHeavyContext);
	if(gHvInputBuffers != NULL)
		free(gHvInputBuffers);
	if(gHvOutputBuffers != NULL)
		free(gHvOutputBuffers);
	delete[] gScopeOut;
}