I am translating an Obj-C app to Swift and having trouble dealing with some syntax. I believe I have declared the variable types correctly so I don't know why I'm be getting these errors. Maybe some blocks are located incorrectly inside classes/functions when they should be outside or something. I would love it if you could review my code. I'm new to programming so what may be a clear and explicit explanation to you probably will still be vague for me so please show with examples using existing names.
Thanks
"Unary operator '++' cannot be applied to an operand of type 'Int?'"
and
"Binary operator '<' cannot be applied to an operand of type 'Int? and Float'"
and
"Use of unresolved identifier '=-'"
import UIKit
import Foundation
import AVFoundation
let minFramesForFilterToSettle = 10
enum CurrentState {
case statePaused
case stateSampling
}
class ViewController: UIViewController, AVCaptureVideoDataOutputSampleBufferDelegate {
let session = AVCaptureSession()
var camera : AVCaptureDevice?
var validFrameCounter: Int = 0
var pulseDetector: PulseDetector!
var filter: Filter!
var currentState = CurrentState.stateSampling // Is this initialized correctly?
override func viewDidLoad() {
super.viewDidLoad()
self.pulseDetector = PulseDetector()
self.filter = Filter()
// TO DO startCameraCapture() // call to un-used function.
}
override func didReceiveMemoryWarning() {
super.didReceiveMemoryWarning()
// Dispose of any resources that can be recreated.
}
}
let NZEROS = 10
let NPOLES = 10
class Filter {
var xv = [Float](count: NZEROS + 1, repeatedValue: 0)
var yv = [Float](count: NPOLES + 1, repeatedValue: 0)
func processValue(value: Float) -> Float {
let gain: Float = 1.894427025e+01
xv[0] = xv[1]; xv[1] = xv[2]; xv[2] = xv[3]; xv[3] = xv[4]; xv[4] = xv[5]; xv[5] = xv[6]; xv[6] = xv[7]; xv[7] = xv[8]; xv[8] = xv[9]; xv[9] = xv[10]; xv[10] = value / gain;
yv[0] = yv[1]; yv[1] = yv[2]; yv[2] = yv[3]; yv[3] = yv[4]; yv[4] = yv[5]; yv[5] = yv[6]; yv[6] = yv[7]; yv[7] = yv[8]; yv[8] = yv[9]; yv[9] = yv[10];
yv[10] = (xv[10] - xv[0]) + 5 * (xv[2] - xv[8]) + 10 * (xv[6] - xv[4])
+ ( -0.0000000000 * yv[0]) + ( 0.0357796363 * yv[1])
+ ( -0.1476158522 * yv[2]) + ( 0.3992561394 * yv[3])
+ ( -1.1743136181 * yv[4]) + ( 2.4692165842 * yv[5])
+ ( -3.3820859632 * yv[6]) + ( 3.9628972812 * yv[7])
+ ( -4.3832594900 * yv[8]) + ( 3.2101976096 * yv[9]);
return yv[10];
}
}
let maxPeriod = 1.5 // float?
let minPeriod = 0.1 // float?
let invalidEntry:Double = -11
let maxPeriodsToStore:Int = 20
let averageSize:Float = 20
class PulseDetector {
var upVals: [Float] = [averageSize]
var downVals: [Float] = [averageSize]
var upValIndex: Int?
var downValIndex: Int?
var lastVal: Float?
var periodStart: Float?
var periods: [Double] = []
var periodTimes: [Double] = []
var periodIndex: Int?
var started: Bool?
var freq: Float?
var average: Float?
var wasDown: Bool?
func reset() {
for var i=0; i < maxPeriodsToStore; i++ {
periods[i] = invalidEntry
}
for var i=0; i < averageSize; i++ { // why error when PulseDetector.h said averageSize was an Int?
upVals[i] = invalidEntry
downVals[i] = invalidEntry
}
freq = 0.5
periodIndex = 0
downValIndex = 0
upValIndex = 0
}
func addNewValue(newVal:Float, atTime:Double) -> Float {
// we keep track of the number of values above and below zero
if newVal > 0 {
upVals[upValIndex!] = newVal
upValIndex++
if upValIndex >= averageSize {
upValIndex = 0
}
}
if newVal < 0 {
downVals[downValIndex] =- newVal
downValIndex++
if downValIndex >= averageSize {
downValIndex = 0
}
}
// work out the average value above zero
var count: Float
var total: Float
for var i=0; i < averageSize; i++ {
if upVals[i] != invalidEntry {
count++
total+=upVals[i]
}
}
var averageUp = total/count
// and the average value below zero
count=0;
total=0;
for var i=0; i < averageSize; i++ {
if downVals[i] != invalidEntry {
count++
total+=downVals[i]
}
}
var averageDown = total/count
// is the new value a down value?
if newVal < (-0.5*averageDown) {
wasDown = true
}
// original Objective-C code
PulseDetector.h
#import <Foundation/Foundation.h>
#define MAX_PERIODS_TO_STORE 20 // is this an Int?
#define AVERAGE_SIZE 20 // is this a Float?
#define INVALID_PULSE_PERIOD -1 // done
@interface PulseDetector : NSObject {
float upVals[AVERAGE_SIZE];
float downVals[AVERAGE_SIZE];
int upValIndex;
int downValIndex;
float lastVal;
float periodStart;
double periods[MAX_PERIODS_TO_STORE]; // this is an array!
double periodTimes[MAX_PERIODS_TO_STORE]; // this is an rray !!
int periodIndex;
bool started;
float freq;
float average;
bool wasDown;
}
@property (nonatomic, assign) float periodStart; // var periodStart = float?
-(float) addNewValue:(float) newVal atTime:(double) time; // declaring a method called addNewValue with 2 arguments called atTime and time that returns a float
-(float) getAverage; // declaring a method called getAverage that returns a float
-(void) reset; // declaring a method that returns nothing
@end
PulseDetector.m
#import <QuartzCore/QuartzCore.h>
#import "PulseDetector.h"
#import <vector>
#import <algorithm>
#define MAX_PERIOD 1.5
#define MIN_PERIOD 0.1
#define INVALID_ENTRY -100 // is this a double?
@implementation PulseDetector
@synthesize periodStart;
- (id) init
{
self = [super init];
if (self != nil) {
// set everything to invalid
[self reset];
}
return self;
}
-(void) reset {
for(int i=0; i<MAX_PERIODS_TO_STORE; i++) {
periods[i]=INVALID_ENTRY;
}
for(int i=0; i<AVERAGE_SIZE; i++) {
upVals[i]=INVALID_ENTRY;
downVals[i]=INVALID_ENTRY;
}
freq=0.5;
periodIndex=0;
downValIndex=0;
upValIndex=0;
}
-(float) addNewValue:(float) newVal atTime:(double) time {
// we keep track of the number of values above and below zero
if(newVal>0) {
upVals[upValIndex]=newVal;
upValIndex++;
if(upValIndex>=AVERAGE_SIZE) {
upValIndex=0;
}
}
if(newVal<0) {
downVals[downValIndex]=-newVal;
downValIndex++;
if(downValIndex>=AVERAGE_SIZE) {
downValIndex=0;
}
}
// work out the average value above zero
float count=0;
float total=0;
for(int i=0; i<AVERAGE_SIZE; i++) {
if(upVals[i]!=INVALID_ENTRY) {
count++;
total+=upVals[i];
}
}
float averageUp=total/count;
// and the average value below zero
count=0;
total=0;
for(int i=0; i<AVERAGE_SIZE; i++) {
if(downVals[i]!=INVALID_ENTRY) {
count++;
total+=downVals[i];
}
}
float averageDown=total/count;
// is the new value a down value?
if(newVal<-0.5*averageDown) {
wasDown=true;
}
// is the new value an up value and were we previously in the down state?
if(newVal>=0.5*averageUp && wasDown) {
wasDown=false;
// work out the difference between now and the last time this happenned
if(time-periodStart<MAX_PERIOD && time-periodStart>MIN_PERIOD) {
periods[periodIndex]=time-periodStart;
periodTimes[periodIndex]=time;
periodIndex++;
if(periodIndex>=MAX_PERIODS_TO_STORE) {
periodIndex=0;
}
}
// track when the transition happened
periodStart=time;
}
// return up or down
if(newVal<-0.5*averageDown) {
return -1;
} else if(newVal>0.5*averageUp) {
return 1;
}
return 0;
}
-(float) getAverage {
double time=CACurrentMediaTime();
double total=0;
double count=0;
for(int i=0; i<MAX_PERIODS_TO_STORE; i++) {
// only use upto 10 seconds worth of data
if(periods[i]!=INVALID_ENTRY && time-periodTimes[i]<10) {
count++;
total+=periods[i];
}
}
// do we have enough values?
if(count>2) {
return total/count;
}
return INVALID_PULSE_PERIOD;
}
@end