# Tag Info

3

var factor = 100; var number = 9.95; var b = number.toString().split('.'); var answer = b[0]*factor+b[1]*(factor/(Math.pow(10,b[1].length))); This is among the most worst solutions but works :P

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You can generally expect the multiplication operator * to be implemented as efficiently as possible. Beating it with a custom multiplication algorithm is highly unlikely. If for any reason multi_2 is faster than multi_1 for all but some edge cases, consider writing a bug report against your compiler vendor. On modern (i.e. made in this century) machines, ...

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The more "high level" your code is, the more optimization paths your compiler will be able to use. So, I'd say that code #1 will have the most chances to produce a fast and optimized code. In fact, for a simple CPU architecture that doesn't support direct multiplication operations, but does support addition and shifts, the second algorithm won't be used at ...

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To answer Q1: '&' is the concatenation operator, so '0' & seven_bit_number makes an 8 bit number. So this whole expression '0' & conv_unsigned(16, 7)(6 downto 1) is a longwinded way of saying B"001000", or 8. I think... Did this come from an Obfuscated VHDL contest? Such laborious fighting with the type system usually means there's something ...

2

For a simpler method, you can use 'System.out.print()' (only works for same length results): for(int i=1; i<=2; i++){ for (int j=1; j <= 2; j++){ //int multiplier =1; int answer = i*j; //multiplier++; System.out.print(answer+" "); } System.out.println(); } Otherwise, you can use 'System.out.format()': ...

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if ( watercom <= 30) printf("your bill is %i", &firstcal); else if (watercom >= 31 && watercom <= 50) printf("your bil is %i", &secondcal); else if (watercom >= 51 && watercom >= 60) printf("your bill is %i", &thirdcal); else if (watercom >= 61) printf("your water bill is %i", fourthcal); There ...

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I don't have skcuda.blas to confirm this. But a more complete example might look like A = np.array(([1, 2, 3], [4, 5, 6])).astype(np.float64) B = np.array(([7, 8], [9, 10], [11, 12])).astype(np.float64) m, k = A.shape k, n = B.shape a_gpu = gpuarray.to_gpu(A) b_gpu = gpuarray.to_gpu(B) c_gpu = gpuarray.empty((m, n), np.float64) alpha = np.float64(1.0) ...

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If a = n*b, n > 0, it is also a = n*b = (1+m)*b = b + m*b, m >= 0. So if a is dividable by b, and a = b+x, then x is also dividable by b. In Peano encoding, n = 1+m is written n = s(m). Take it from here.

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All fixed now, just took some tweaking. The issue was solved by Bruno and Chris, the error was that my inputs weren't integers, after changing the inputs, the code is working perfectly. Thanks to everyone who helped!

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I don't think there exists a method for your specific problem, but with a little thought you might be able to build an algorithm from the low-level BLAS routines that are wrapped in SciPy. For example, dgemm, dsymm, and dtrmm do general, symmetric, and triangular matrix products respectively. Here's an example of using them: from scipy.linalg.blas import ...

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Python stores floating point decimals in base-2. https://docs.python.org/2/tutorial/floatingpoint.html This means that some decimals could be terminating in base-10, but are repeating in base-2, hence the floating-point error when you add them up. This gets into some math, but imagine in base-10 trying to express the value 2/6. When you eliminate the ...

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for (int R = 0; R <U.size(); ++R) { Voltage[R] = U[R]*V[R]; } Here is your first issue. Voltage is an empty vector and you are trying to put something where nothing exists. Try creating your vector like vector<double> voltage(U.size()); That should help. Also, I'm surprised you don't get an error for the possibility that you may not ...

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Typical modern CPUs can do multiplication in hardware, often at the same speed as addition. So clearly #1 is better. Even if multiplication is not available and you are stuck with addition there are algorithms much faster than #2.

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