# Tag Info

8

No, you must restrict yourself from casting. With large enough values, e.g. 1000000000L / 1000000001L is clearly 0, but when cast to float, it gives 1.0, since (float)a == (float)a+1. main() { int a = 1000000000; printf("%d\n%d", a/(a+1), (int)((float)a/(a+1))); } Output: 0 1

4

This is the nature of floating point - there is no way to represent 2.3 exactly as a floating point binary. The "2.3" in your first test can't be represented exactly in binary, so it's stored as the closest possible double, which is 2.2999999999999998. In other words, both ifs perform the same comparison.

3

1.0 and 2.0 are doubles. Arithmetic between doubles and floats will implicitly convert the floats to doubles. You need to force the entire expression to use floats by adding the f suffix to all of your literals.

3

It was not clear from the question that you want the setprecision to modify how fprintf works; it's only clear from the comments. This is impossible (at least, with the existing C++ standard library). The stdio and iostreams systems are separate, mostly independent parts in C++. In addition, the iostreams stuff was standardized after the stdio stuff, so to ...

3

When you use sed 's/.00//' it basically means match any character (meaning of .) followed by 00 and replace it with nothing. So when you have 100.00 in your output, sed duly removes 100 from it and gives you .00. What you really need is to escape the special character with \ ... | sed 's/\..*//'

3

The "fill character" is used to fill up the field to the specified width. By default, these characters are added to the left, such that the output will be right aligned. You can use std::left for left alignment. For numbers, the additional option std::internal will fill the space between the sign and the actual digits: cout << setw(5) << ...

2

This isn't a NumPy issue. Your expectation that the result should be -1 is incorrect. You're effectively computing the definite integral of a function f(x) on a large interval around 5100. The function you're integrating simplifies to factor * x * gaussian(x) / (1 - factor * x). We can easily give a back-of-the-envelope estimate for the value of the ...

2

If you have two variables x and y, with y = 1 - x, then you really have a problem in just one variable x. Noting that, you can reparametrise your function to be 1 - 2 * x + x^2 - 2 * (1 - x) + 2 * x * (1 - x) + (1 - x)^2 and going through the algebra shows that this is constant as a function of x. Thus any value of x in (0, 1) is a solution, and which one ...

2

The basic problem is: Given two calculated values, a and b, that would be a and b if calculated exactly but that differ because of floating-point rounding, what can we determine about a and b regarding less than, equal to, and greater than? Suppose we know the maximum possible total error in a and b is e. Then we can determine one of: If a – b < –e, ...

2

Executed in 80 decimal digits precision, the result starts with 0.4464455542636494555603375755720232254414694834911 An error analysis of the algorithm shows that in each step, the previous error is multiplied by about pi (and the cosine of the current point), i.e., about 3, and the current floating point error added as noise. So the margin of error is 3^25 ...

2

Try this: bat_percent=`echo "\$bat_percent * 100" | bc | sed 's/\.00//'` The problem with your sed command is that you haven't escaped the . as \. to use it as a literal; an unescaped . in a regular expression matches ANY character. If the input is "100.00", /.00/ matches 100 (because ., due to matching any char., matches the 1), not .00. Alternatively, ...

2

You are missing many points here, you should capture all points here rather than capturing historical points only. Check this - http://www.codeproject.com/Articles/458042/Touch-handling-in-Android

2

Both solutions are acceptable. However, it is interested question, so I tried to compute proccesing time using this code : double d = 81.2384; double l1 = 0, l2 = 0; Long start = System.nanoTime(); for (int i = 0; i < 1000 * 1000 * 100; i++) { l1 = d - d % 0.1; } Long time = System.nanoTime(); Long l1speed = time - ...

2

In Java there is a BigInteger class, for when you need unlimited precision using whole numbers. For decimal numbers, use BigDecimal Wolfram Alpha will give you 2.243754834308400900535121747859167616725725368773485418854923..., and our figure is 2.243754834308401, which is same as bigDecimal1.divide(bigDecimal2, MathContext.DECIMAL64) If you will go for ...

2

For C99, there are no specific requirements. But most implementations support Annex F: IEC 60559 ﬂoating-point arithmetic. It says: An implementation that deﬁnes __STDC_IEC_559__ shall conform to the specifications in this annex. And: The sqrt functions in <math.h> provide the IEC 60559 square root operation. IEC 60559 (equivalent to IEEE ...

1

If you check the calculation in Wolfram Alpha, you'll see that the exact result is 2.243754834308400900535121747859167616725725368773485418854923... Your figure of 2.243754834308401 is dead on. Unless you need more precision, the calculation with doubles will suffice.

1

GMP is designed to have arbitrary precision with support for C++ using the gmpxx.h header, and corresponding library. If you're building GMP from scratch, use --enable-cxx flag during configure. To construct an object from std::string, simply use the constructor, for example, #include <gmpxx.h> const std::string longNumber = "12345678901234567890"; ...

1

You can use the floor function to round your numbers down: plot 'datafile' using 1:2:(floor(\$3*1e1)/1e1) with image This sets all your numbers to 1 decimal place. If you wanted to do the same thing for a higher number of decimal places, you could change the 1e1 to 1eN, where N is the number of decimal places you want.

1

There is another problem: echoing float value. You have to increase your precision. echo 1 / 3, PHP_EOL; // 0.33333333333333 ini_set('precision', 60); echo 1 / 3, PHP_EOL; // 0.333333333333333314829616256247390992939472198486328125 Why are you trying to use value from screen but not from variable?

1

You can use a DecimalFormat: double d = 81.2384; DecimalFormat df = new DecimalFormat("#.##"); System.out.print(df.format(d)); which will print: 81.23

1

Bitcoin amounts can range from 1 Satoshi (0.00000001 BTC) to nearly 2,100,000,000,000,000 (21,000,000 BTC). To avoid rounding errors, you must make sure your PHP implementation supports the full range of Bitcoin values without losing precision. Most PHP implementations use IEEE 64-bit double-precision floating point numbers with 53 bits of ...

1

From the help file of ?adf.test: The p-values are interpolated from Table 4.2, p. 103 of Banerjee et al. (1993). If the computed statistic is outside the table of critical values, then a warning message is generated. So the short answer is no, you cannot get "more precise" p-values. At least not directly. Anyway, usually it does not make much sense ...

1

Here is a much simpler solution for you... Use the rational representation of 4+sqrt(11): BigInteger hundred = new BigInteger("100"); BigInteger numerator = new BigInteger("5017987099799880733320738241"); BigInteger denominator = new BigInteger("685833597263928519195691392"); BigInteger result = ...

1

At n=22 the results seem to repeat from the position of n=2. So keep those 20 values in an array in the same order as in your list e.g. nums[20]. Then when the user provides an n: return nums[(n-2)%20] There is now a proof of this pattern repeating here. Alternatively, if you insist on computing at length; since you calculating the power by looping ...

1

If you are trying to work with numbers requiring precision beyond the JavaScript float (only 64 bits of precision) you could consider using a library like one of those mentioned in this question: Is there a decimal math library for JavaScript? In particular the bignumber library looks promising for your purposes. Here is a quick demonstration jsfiddle: ...

1

This is because the optional size argument of fread is a numeric, not a string. That is, instead of 'inf', the appropriate input is just inf, a number, not a string. When you input a string to fread, it thinks you are specifying a precision instead of a size. However, the default size is inf, which is why the argument may be omitted.

1

I have the same error message in Octave and removing 'inf' solved the problem close all; clear all; fid = fopen('mHSdark_20ms_00014.bin'); A = fread(fid, 'uint16'); fclose(fid); size(A) Here is an execution result octave:5> test ans = 20480 1

1

I can't speak to these particular packages, but nloptr(...) in package nloptr seems to work well: # Non-Linear Optimization (package::nloptr) F <- function(v){ x=v[1] y=v[2] output <- 1 - 2 * x + x^2 - 2 * y + 2 * x * y + y^2 } Hc <- function(v) return(1-sum(v)) library(nloptr) opt <- nloptr(x0=c(1/2,1/2), eval_f=F, lb = c(0,0), ub = ...

1

The answers to the question this will be closed as a duplicate of explains what is going on. But for a quick little thing hopefully this helps: > options(digits = 22) > .1 + .2 - 0.4 [1] -0.09999999999999997779554 > 0.1 [1] 0.1000000000000000055511 > 0.2 [1] 0.2000000000000000111022 > 0.4 [1] 0.4000000000000000222045 You can't represent ...

1

You can set the display precision with something like options(digits=10) But this doesn't affect the actual precision of the calculation - most non-integer-values (such as 0.1) cannot be represented exactly in floating point arithmetic. See here for an introduction into floating point arithmetic: ...

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