Is there any standard C++ way (e.g. class library) which provides integer multiplication with double precision? What I mean is: given two unsigned int's a,b the multiplication of them should give me an array of two unsigned int's {c, d} such that a*b = c + d*(UINT_MAX+1) ?
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1Are you talking about fixed point multiplication?– secretformulaAug 23, 2011 at 15:54
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No, I guess not. I am talking about multiplication of natural numbers. Fixed point means that you have numbers in decimal notation with a fixed number of positions before and after the comma, isn't it? Idon't have any comma here.– Christian LompAug 23, 2011 at 16:09
5 Answers
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Or code your own, I found switching to double (real - fp type) to afford sufficient precision for my needs, but got close to coding my own :)– JohnAug 23, 2011 at 16:00
If you are restricted to the C++ standard libraries, the answer is no, there is no such predefined type. You can confirm that here. @DumbCoder suggested an alternative
I'm not sure if this solves the problem, but as a crude built-in solution, you may try to use unsigned long long int
, which is a 64-bit integer.
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Don't you mean
unsigned long long
? @John Silver:unsigned long long
was added to C++0x, so it is now part of the standard. Aug 23, 2011 at 16:03 -
unsigned long long int
andunsigned long long
are names for the same time. Aug 23, 2011 at 16:12 -
Thanks for the comment. I tried this with g++, but
unsigned long long (int)
seems to have the same size asUINT_MAX.
(Which results in 1 if you multiplyUINT_MAX * UINT_MAX
). Aug 23, 2011 at 16:13 -
1@Christian: you should multiply
((unsigned long long)UINT_MAX) * UINT_MAX
. The type of an arithmetic expression only depends on the types of the operands, not the type you store it in: ideone.com/yvw0U Aug 23, 2011 at 16:30
You were on the right track with splitting up the multiplication into pieces, except where you had h=(UINT_MAX+1)/2 it should be h=sqrt(UINT_MAX+1). If you have 32-bit integers for example h=0x10000. Multiplying by such a constant is the same as shifting left by a number of bits, so your equation becomes:
a0 = a & 0xffff;
a1 = a >> 16;
b0 = b & 0xffff;
b1 = b >> 16;
a*b = a0*b0 + ((a1*b0)<<16 + (a0*b1)<<16) + (a1*b1)<<32
Since each component is 16 bits or less, each multiplication is guaranteed to fit into an unsigned 32 bit result.
For adding multiple-precision values together, see How can I add and subtract 128 bit integers in C or C++ if my compiler does not support them?