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utility.h
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utility.h
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#ifndef UTILITY_H
#define UTILITY_H
#include <Qt>
#include <stdint.h>
#include <QByteArray>
#include <QDateTime>
#include <QDebug>
#include <QApplication>
#include <QRect>
#include <QComboBox>
#include <QStandardItemModel>
//#include <QDesktopWidget>
enum TimeStyle
{
TS_SECONDS,
TS_MICROS,
TS_MILLIS,
TS_CLOCK
};
class Utility
{
public:
static bool decimalMode;
static TimeStyle timeStyle;
static QString timeFormat;
static QString fullyQualifiedNameSeperator;
static void SetComboBoxItemEnabled(QComboBox * comboBox, int index, bool enabled)
{
auto * model = qobject_cast<QStandardItemModel*>(comboBox->model());
assert(model);
if(!model) return;
auto * item = model->item(index);
assert(item);
if(!item) return;
item->setEnabled(enabled);
}
//determines whether the window position is within any available screens. If it is not we default
//back to 0,0 which is going to be on screen. This fixes a problem where some operating systems would
//otherwise let you put windows on a second monitor, disconnect that monitor, and still put windows on it.
static QPoint constrainedWindowPos(QPoint originalPos)
{
QScreen *screen = QGuiApplication::screenAt(originalPos);
if (!screen)
{
return QPoint(0,0);
}
return originalPos;
}
static QString unQuote(QString inStr)
{
QStringList temp;
temp = inStr.split('\"');
if (temp.length() >= 3)
return temp[1];
return inStr;
}
static uint64_t ParseStringToNum(QByteArray input)
{
uint64_t temp = 0;
input = input.toUpper();
if (input.startsWith("0X") || input.startsWith("X")) //hex number
{
if (input.length() < 3) temp = 0;
else temp = input.right(input.size() - 2).toLongLong(nullptr, 16);
}
else if (input.startsWith("0B") || input.startsWith("B")) //binary number
{
input = input.right(input.size() - 1); //remove the B
for (int i = 0; i < input.length(); i++)
{
if (input[i] == '1') temp += (uint64_t)1 << (input.length() - i - 1);
}
}
else //decimal number
{
temp = input.toLongLong();
}
return temp;
}
static uint64_t ParseStringToNum(QString input)
{
return ParseStringToNum(input.toUtf8());
}
static uint ParseStringToNum2(QString pInput, bool* pOk_p = nullptr)
{
if(pInput.startsWith("0b"))
{
pInput.remove(0, 2);
return pInput.toUInt(pOk_p, 2);
}
return pInput.toUInt(pOk_p, 0);
}
static uint64_t GetTimeMS()
{
QDateTime stamp = QDateTime::currentDateTime();
return (((static_cast<uint64_t>(stamp.time().hour()) * 3600ull) + (static_cast<uint64_t>(stamp.time().minute()) * 60ull)
+ (static_cast<uint64_t>(stamp.time().second())) * 1000ull) + static_cast<uint64_t>(stamp.time().msec()));
}
//prints hex numbers in uppercase with 0's filling out the number depending
//on the size needed. Promotes hex numbers to either 2, 4, or 8 digits
static QString formatHexNum(uint64_t input)
{
if (input < 256)
return "0x" + QString::number(input, 16).toUpper().rightJustified(2,'0');
if (input < 65536)
return "0x" + QString::number(input, 16).toUpper().rightJustified(4,'0');
if (input < 4294967296)
return "0x" + QString::number(input, 16).toUpper().rightJustified(8,'0');
return "0x" + QString::number(input, 16).toUpper().rightJustified(16,'0');
}
//uses decimalMode to see if it should show value as decimal or hex
static QString formatNumber(uint64_t value)
{
if (decimalMode)
{
return QString::number(value, 10);
}
else return formatHexNum(value);
}
static QString formatCANID(uint64_t id, bool extended)
{
if (decimalMode) return QString::number(id, 10);
if (extended)
{
return "0x" + QString::number(id, 16).toUpper().rightJustified(8,'0');
}
else
{
id = id & 0x7FF;
return "0x" + QString::number(id, 16).toUpper().rightJustified(3,'0');
}
}
static QString formatCANID(uint64_t id)
{
if (id < 0x800) return formatCANID(id, false);
return formatCANID(id, true);
}
static QString formatByteAsBinary(uint8_t value)
{
QString output;
for (int b = 7; b >= 0; b--)
{
if (value & (1 << b)) output += "1";
else output += "0";
}
return output;
}
static QString formatByteAsHex(uint8_t value)
{
return QString::number(value, 16).toUpper().rightJustified(2,'0');
}
static QVariant formatTimestamp(uint64_t timestamp)
{
switch (timeStyle)
{
case TS_CLOCK:
return QDateTime::fromMSecsSinceEpoch(timestamp / 1000);
break;
case TS_MILLIS:
return (double)timestamp / 1000.0;
break;
case TS_MICROS:
return (unsigned long long)(timestamp);
break;
case TS_SECONDS:
return (double)timestamp / 1000000.0;
break;
}
return QVariant(); // should never happen
}
//parses the input string to grab as much of it as possible while staying alpha numeric
static QString grabAlphaNumeric(QString &input)
{
QString builder;
QChar thisChar;
for (int i = 0; i < input.length(); i++)
{
thisChar = input[i];
if (thisChar.isLetterOrNumber() || thisChar == ':' || thisChar == '~') builder.append(input[i]);
else
{
//qDebug() << "i: "<< i << " len: " << input.length();
if (i < (input.length() - 1)) input = input.right(input.length() - i);
else input = "";
return builder;
}
}
//qDebug() << "Reached end of string in grabAlphaNumeric";
input = "";
return builder;
}
static QString grabOperation(QString &input)
{
QString builder;
QChar thisChar = input[0];
if (thisChar == '+' || thisChar == '-' || thisChar == '*' || thisChar == '/' || thisChar == '^' || thisChar == '&' || thisChar == '|' || thisChar == '=' || thisChar == '%')
{
input = input.right(input.length() - 1);
builder = thisChar;
}
return builder;
}
static int getByteFromBitPosition(int bitPos)
{
return bitPos / 8;
}
static int getBitFromBitPosition(int bitPos)
{
return bitPos & 7;
}
//simple linear interpolation between value1 and value2. sample point is 0.0 to 1.0
static double Lerp(double value1, double value2, double samplePoint)
{
return (value1 * (1.0 - samplePoint)) + (value2 * samplePoint);
}
/* A unified function that can extract a signal from the (up to) 64 bits of data bytes in a CAN frame
* handles both little and big endian signals (and floats too).
*/
static int64_t processIntegerSignal(const QByteArray data, int startBit, int sigSize, bool littleEndian, bool isSigned)
{
uint64_t result = 0;
int bit = 0;
int maxBytes = (startBit + sigSize) / 8;
if (data.size() < maxBytes) return 0; //if signal extends past the end of data then abort
if (littleEndian)
{
/*
int currByte = (startBit) / 8;
int currOffset = startBit - (currByte * 8);
int remainingBits = qMax(0, (sigSize - (8 - currOffset)) );
int prevBits = qMin((8 - currOffset), sigSize);
result = data[currByte] >> currOffset;
result &= ( (1 << sigSize) - 1); //doesn't hurt to do this even if sigSize is way larger than the # of bits we've got so far
while (remainingBits > 0)
{
currByte++;
if (remainingBits >= 8) //use this entire byte, its easy
{
result += data[currByte] << prevBits;
remainingBits -= 8;
prevBits += 8;
}
else //use only part of this byte. We're going to need to mask it
{
result += ((data[currByte] & ((1 << remainingBits) - 1) ) << prevBits);
remainingBits = 0;
}
}*/
bit = startBit;
for (int bitpos = 0; bitpos < sigSize; bitpos++)
{
if (bit < 512) {
int bytePos = bit / 8;
if (bytePos >= data.count()) return 0; //error!
if (data[bit / 8] & (1 << (bit % 8)))
result += (1ULL << bitpos);
}
bit++;
}
}
else //motorola / big endian mode
{
bit = startBit;
for (int bitpos = 0; bitpos < sigSize; bitpos++)
{
if (bit < 512) {
int bytePos = bit / 8;
if (bytePos >= data.count()) return 0; //error!
if (data[bit / 8] & (1 << (bit % 8)))
result += (1ULL << (sigSize - bitpos - 1));
}
if ((bit % 8) == 0)
bit += 15;
else bit--;
}
}
if (isSigned)
{
uint64_t mask = (1ULL << (sigSize - 1));
if ((result & mask) == mask) //is the highest bit possible for this signal size set?
{
/*
* if so we need to also set every bit higher in the result int too.
* This leads to the below two lines that are nasty. Here's the theory behind that...
* If the value is signed and the highest bit is set then it is negative. To create
* a negative value out of this even though the variable result is 64 bit we have to
* run 1's all of the way up to bit 63 in result. -1 is all ones for whatever size integer
* you have. So, it's 64 1's in this case.
* signedMask is done this way:
* first you take the signal size and shift 1 up that far. Then subtract one. Lets
* see that for a 16 bit signal:
* (1 << 16) - 1 = the first 16 bits set as 1's. So far so good. We then negate the whole
* thing which flips all bits. Thus signedMask ends up with 1's everwhere that the signal
* doesn't take up in the 64 bit signed integer result. Then, result has an OR operation on
* it with the old value and -1 masked so that the the 1 bits from -1 don't overwrite bits from the
* actual signal. This extends the sign bits out so that the integer result reads as the proper negative
* value. We dont need to do any of this if the sign bit wasn't set.
*/
uint64_t signedMask = ~((1ULL << sigSize) - 1);
result = (-1LL & signedMask) | result;
return (int64_t)(result);
}
}
return result;
}
};
#endif // UTILITY_H