/// -*- tab-width: 4; Mode: C++; c-basic-offset: 4; indent-tabs-mode: nil -*-

#if FRAME_CONFIG ==	QUAD_FRAME

static void init_motors_out()
{
	#if INSTANT_PWM == 0
    APM_RC.SetFastOutputChannels( _BV(MOT_1) | _BV(MOT_2) | _BV(MOT_3) | _BV(MOT_4) );
	#endif
}

static void output_motors_armed()
{
	int roll_out, pitch_out;
	int out_min = g.rc_3.radio_min;
	int out_max = g.rc_3.radio_max;

	// Throttle is 0 to 1000 only
	g.rc_3.servo_out 	= constrain(g.rc_3.servo_out, 0, MAXIMUM_THROTTLE);

	if(g.rc_3.servo_out > 0)
		out_min = g.rc_3.radio_min + MINIMUM_THROTTLE;

	g.rc_1.calc_pwm();
	g.rc_2.calc_pwm();
	g.rc_3.calc_pwm();
	g.rc_4.calc_pwm();



	if(g.frame_orientation == X_FRAME){
		roll_out 	 	= g.rc_1.pwm_out * .707;
		pitch_out 	 	= g.rc_2.pwm_out * .707;

		// left
		motor_out[MOT_3]	 	= g.rc_3.radio_out + roll_out + pitch_out;	// FRONT
		motor_out[MOT_2]	 	= g.rc_3.radio_out + roll_out - pitch_out;	// BACK

		// right
		motor_out[MOT_1]		= g.rc_3.radio_out - roll_out + pitch_out;  // FRONT
		motor_out[MOT_4] 	= g.rc_3.radio_out - roll_out - pitch_out;	// BACK

	}else{

		roll_out 	 	= g.rc_1.pwm_out;
		pitch_out 	 	= g.rc_2.pwm_out;

		// right motor
		motor_out[MOT_1]		= g.rc_3.radio_out - roll_out;
		// left motor
		motor_out[MOT_2]		= g.rc_3.radio_out + roll_out;
		// front motor
		motor_out[MOT_3]		= g.rc_3.radio_out + pitch_out;
		// back motor
		motor_out[MOT_4] 	= g.rc_3.radio_out - pitch_out;
	}

	// Yaw input
	motor_out[MOT_1]		+=  g.rc_4.pwm_out; 	// CCW
	motor_out[MOT_2]		+=  g.rc_4.pwm_out; 	// CCW
	motor_out[MOT_3]		-=  g.rc_4.pwm_out; 	// CW
	motor_out[MOT_4] 	-=  g.rc_4.pwm_out; 	// CW

    /* We need to clip motor output at out_max. When cipping a motors
     * output we also need to compensate for the instability by
     * lowering the opposite motor by the same proportion. This
     * ensures that we retain control when one or more of the motors
     * is at its maximum output
     */
    for (int i=MOT_1; i<=MOT_4; i++) {
        if (motor_out[i] > out_max) {
            // note that i^1 is the opposite motor
            motor_out[i^1] -= motor_out[i] - out_max;
            motor_out[i] = out_max;
        }
    }

	// limit output so motors don't stop
	motor_out[MOT_1]		= max(motor_out[MOT_1], 	out_min);
	motor_out[MOT_2]		= max(motor_out[MOT_2], 	out_min);
	motor_out[MOT_3]		= max(motor_out[MOT_3], 	out_min);
	motor_out[MOT_4] 	= max(motor_out[MOT_4], 	out_min);

	#if CUT_MOTORS == ENABLED
	// if we are not sending a throttle output, we cut the motors
	if(g.rc_3.servo_out == 0){
		motor_out[MOT_1]		= g.rc_3.radio_min;
		motor_out[MOT_2]		= g.rc_3.radio_min;
		motor_out[MOT_3]		= g.rc_3.radio_min;
		motor_out[MOT_4] 	= g.rc_3.radio_min;
	}
	#endif

	// this filter slows the acceleration of motors vs the deceleration
	// Idea by Denny Rowland to help with his Yaw issue
	for(int8_t i=MOT_1; i <= MOT_4; i++ ) {
		if(motor_filtered[i] < motor_out[i]){
			motor_filtered[i] = (motor_out[i] + motor_filtered[i]) / 2;
		}else{
			// don't filter
			motor_filtered[i] = motor_out[i];
		}
	}

	APM_RC.OutputCh(MOT_1, motor_filtered[MOT_1]);
	APM_RC.OutputCh(MOT_2, motor_filtered[MOT_2]);
	APM_RC.OutputCh(MOT_3, motor_filtered[MOT_3]);
	APM_RC.OutputCh(MOT_4, motor_filtered[MOT_4]);

	#if INSTANT_PWM == 1
	// InstantPWM
	APM_RC.Force_Out0_Out1();
	APM_RC.Force_Out2_Out3();
	#endif

	//debug_motors();
}

static void output_motors_disarmed()
{
	if(g.rc_3.control_in > 0){
		// we have pushed up the throttle
		// remove safety
		motor_auto_armed = true;
	}

	// fill the motor_out[] array for HIL use
	for (unsigned char i = 0; i < 8; i++) {
		motor_out[i] = g.rc_3.radio_min;
	}

	// Send commands to motors
	APM_RC.OutputCh(MOT_1, g.rc_3.radio_min);
	APM_RC.OutputCh(MOT_2, g.rc_3.radio_min);
	APM_RC.OutputCh(MOT_3, g.rc_3.radio_min);
	APM_RC.OutputCh(MOT_4, g.rc_3.radio_min);
}

/*
//static void debug_motors()
{
	Serial.printf("1:%d\t2:%d\t3:%d\t4:%d\n",
				motor_out[MOT_1],
				motor_out[MOT_2],
				motor_out[MOT_3],
				motor_out[MOT_4]);
}
//*/

static void output_motor_test()
{
	motor_out[MOT_1] = g.rc_3.radio_min;
	motor_out[MOT_2] = g.rc_3.radio_min;
	motor_out[MOT_3] = g.rc_3.radio_min;
	motor_out[MOT_4] = g.rc_3.radio_min;


	if(g.frame_orientation == X_FRAME){
//  31
//	24
		if(g.rc_1.control_in > 3000){
			motor_out[MOT_1] += 100;
			motor_out[MOT_4] += 100;
		}

		if(g.rc_1.control_in < -3000){
			motor_out[MOT_2] += 100;
			motor_out[MOT_3] += 100;
		}

		if(g.rc_2.control_in > 3000){
			motor_out[MOT_2] += 100;
			motor_out[MOT_4] += 100;
		}

		if(g.rc_2.control_in < -3000){
			motor_out[MOT_1] += 100;
			motor_out[MOT_3] += 100;
		}

	}else{
//  3
// 2 1
//	4
		if(g.rc_1.control_in > 3000)
			motor_out[MOT_1] += 100;

		if(g.rc_1.control_in < -3000)
			motor_out[MOT_2] += 100;

		if(g.rc_2.control_in > 3000)
			motor_out[MOT_4] += 100;

		if(g.rc_2.control_in < -3000)
			motor_out[MOT_3] += 100;
	}

	APM_RC.OutputCh(MOT_1, motor_out[MOT_1]);
	APM_RC.OutputCh(MOT_2, motor_out[MOT_2]);
	APM_RC.OutputCh(MOT_3, motor_out[MOT_3]);
	APM_RC.OutputCh(MOT_4, motor_out[MOT_4]);
}

#endif