private static bool DisplayPotentiometerInfoAndCheckForCancel(MCP41X1_Base ldp, bool tryReadValue = false, int exWaitTime = -1)
{
Console.WriteLine(ldp.ToString());
if(exWaitTime == -1)
TimePeriod.Sleep(_waitTime * 1);
else
if (exWaitTime >0) TimePeriod.Sleep(exWaitTime);
if (tryReadValue)
{
int val = ldp.Get();
}
if (Console.KeyAvailable) {
var k = Console.ReadKey();
return true;
}
else return false;
}
private bool Animate(MCP41X1_Base.ADDRESS pot, AnimationDsl animationType, int wait, int count = 1)
{
var steps = new List<int>();
if (animationType == AnimationDsl.FadeInFadeOut) {
Animate(pot, AnimationDsl.FadeIn, wait);
Animate(pot, AnimationDsl.Pause, wait);
Animate(pot, AnimationDsl.FadeOut, wait);
}
else if (animationType == AnimationDsl.FadeIn) {
steps = _stepsDefinition[pot];
}
else if (animationType == AnimationDsl.FadeOut) {
steps = new List<int>(_stepsDefinition[pot]);
steps.Reverse();
}
else if (animationType == AnimationDsl.Pause) {
TimePeriod.Sleep(wait*2);
return true;
}
else if (animationType == AnimationDsl.Off) {
this.Set(0, pot);
return true;
}
else if (animationType == AnimationDsl.Max) {
steps = _stepsDefinition[pot];
this.Set(steps[steps.Count-1], pot);
return true;
}
else if (animationType == AnimationDsl.HalfMax) {
steps = _stepsDefinition[pot];
this.Set(steps[steps.Count/2], pot);
return true;
}
else if (animationType == AnimationDsl.Blink) {
MCP41X1_Base.ADDRESS Led1 = pot;
MCP41X1_Base.ADDRESS Led2 = Led1 == Red ? Green : Red;
for (var c = 0; c < count; c++) {
Animate(Led1, AnimationDsl.Off, wait);
TimePeriod.Sleep(wait);
Animate(Led1, AnimationDsl.Max, wait);
TimePeriod.Sleep(wait);
}
return true;
}
else if (animationType == AnimationDsl.BlinkWithOtherColor) {
MCP41X1_Base.ADDRESS Led1 = pot;
MCP41X1_Base.ADDRESS Led2 = Led1 == Red ? Green : Red;
for (var c = 0; c < count; c++) {
Animate(Led1, AnimationDsl.Off, wait);
Animate(Led2, AnimationDsl.Max, wait);
TimePeriod.Sleep(wait);
Animate(Led2, AnimationDsl.Off, wait);
Animate(Led1, AnimationDsl.Max, wait);
TimePeriod.Sleep(wait);
}
return true;
}
else throw new ArgumentException();
foreach (var s in steps)
{
if (!this.Set(s, pot).Succeeded)
Console.WriteLine("Communication error");
TimePeriod.Sleep(wait);
}
return true;
}
static void OtherApiTests(MCP41X1_Base dp)
{
var quit = false;
Console.Clear();
try
{
var expectedValue = 0;
dp.Set(0);
for (var i = 0; i <= dp.MaxDigitalValue; i += _demoStep)
{
expectedValue += _demoStep;
if(expectedValue > dp.MaxDigitalValue)
expectedValue = dp.MaxDigitalValue;
if(DisplayPotentiometerInfoAndCheckForCancel(dp)) { quit = true; break;}
dp.Increment(_demoStep);
var v = dp.Get();
if(expectedValue != v)
Console.WriteLine("Method Get() did not return expected result");
}
if(quit)
return;
dp.Set(dp.MaxDigitalValue);
DisplayPotentiometerInfoAndCheckForCancel(dp);
expectedValue = dp.MaxDigitalValue;
for (var i = dp.MaxDigitalValue; i > 0; i -= _demoStep)
{
expectedValue -= _demoStep;
if(expectedValue < dp.MinDigitalValue)
expectedValue = dp.MinDigitalValue;
if(DisplayPotentiometerInfoAndCheckForCancel(dp)) { quit = true; break;}
dp.Decrement(_demoStep);
var v = dp.Get();
if(expectedValue != v)
Console.WriteLine("Method Get() did not return expected result");
}
}
finally
{
dp.Set(0);
}
}
static void TestDigitalPotRange(MCP41X1_Base dp, bool tryReadValue = false)
{
Console.Clear();
for (var i = dp.MinDigitalValue; i <= dp.MaxDigitalValue; i += _demoStep)
{
if (!dp.Set(i).Succeeded)
Console.WriteLine("Communication error");
if(DisplayPotentiometerInfoAndCheckForCancel(dp, tryReadValue))
break;
}
dp.Set(0);
}
static bool AnimateOneLed(MCP4231 dp, MCP41X1_Base.ADDRESS pot0, MCP41X1_Base.ADDRESS? pot1, int wait)
{
int startStep = 38;
int step = 4;
for (var i = startStep; i <= dp.MaxDigitalValue; i += step)
{
if (!dp.Set(i, pot0).Succeeded) Console.WriteLine("Communication error");
if(pot1.HasValue)
if (!dp.Set(i, pot1.Value).Succeeded) Console.WriteLine("Communication error");
if(DisplayPotentiometerInfoAndCheckForCancel(dp, exWaitTime:wait))
return true; // Quit
}
for (var i = dp.MaxDigitalValue; i > startStep; i -= step)
{
if (!dp.Set(i, pot0).Succeeded) Console.WriteLine("Communication error");
if(pot1.HasValue)
if (!dp.Set(i, pot1.Value).Succeeded) Console.WriteLine("Communication error");
if(DisplayPotentiometerInfoAndCheckForCancel(dp, exWaitTime:wait))
return true; // Quit
}
return false;
}
static void OtherApiTests(MCP41X1_Base dp)
{
var quit = false;
Console.Clear();
try {
dp.Set(0);
for (var i = 0; i <= dp.MaxDigitalValue; i += demoStep)
{
if(DisplayPotentiometerInfoAndCheckForCancel(dp)) { quit = true; break;}
dp.Increment(demoStep);
}
if(quit)
return;
dp.Set(dp.MaxDigitalValue);
DisplayPotentiometerInfoAndCheckForCancel(dp);
for (var i = dp.MaxDigitalValue; i > 0; i -= demoStep)
{
if(DisplayPotentiometerInfoAndCheckForCancel(dp)) { quit = true; break;}
dp.Decrement(demoStep);
}
}
finally
{
dp.Set(0);
}
}
static void DigitalPotRangeForLed(MCP41X1_Base dp)
{
Console.Clear();
var quit = false;
var ledThreadHold17Volt = 0;
dp.Set(0);
int wait = 16;
while (!quit)
{
for (var i = ledThreadHold17Volt; i <= dp.MaxDigitalValue; i += 1)
{
if (!dp.Set(i).Succeeded)
Console.WriteLine("Communication error");
if(DisplayPotentiometerInfoAndCheckForCancel(dp, exWaitTime:wait)) { quit = true; break; }
}
if(DisplayPotentiometerInfoAndCheckForCancel(dp, exWaitTime:wait)) { quit = true; break; }
//_mcp4131_10k.Set(dp.MaxDigitalValue);
//TimePeriod.Sleep(waitTime * 10);
//for (var i = 0; i < 5; i++) {
// dp.Set(0);
// TimePeriod.Sleep(waitTime*2);
// _mcp4131_10k.Set(dp.MaxDigitalValue);
// TimePeriod.Sleep(waitTime*3);
//}
for (var i = dp.MaxDigitalValue; i > ledThreadHold17Volt; i -= 1)
{
if (!dp.Set(i).Succeeded)
Console.WriteLine("Communication error");
if(DisplayPotentiometerInfoAndCheckForCancel(dp, exWaitTime:wait)) { quit = true; break; }
}
//TimePeriod.Sleep(waitTime*10);
if(DisplayPotentiometerInfoAndCheckForCancel(dp, exWaitTime:wait)) { quit = true; break; }
}
var k = Console.ReadKey();
dp.Set(0);
}
