# Tag Info

2

I would question whether it makes sense to hash UTF-16LE ("Unicode") this way. It might make a lot more sense to convert your VB String to UTF-8 and then hash that. While I can't find any test vectors for djb2 to validate my own implementation it seems to run quite quickly: Private Type CURRENCY_CURRENCY Value As Currency End Type Private Type ...

1

I found a workaround using Currency and doing the overflow math myself (and it turns out that VB6 Mod operator also won't work on Currency): Public Function simpleHash(hashString As String) As Long Dim hash As Currency Dim c As Long Dim i As Integer Dim pow2_32 As Currency: pow2_32 = 2@ ^ 32 Dim signed32Max As Currency: signed32Max = 2@ ^ 31 - 1 On ...

2

The mulmod routine can be speeded up by a large factor K. 1) '%' is overkill, since (a + b) are both less than N. - It's enough to evaluate c = a+b; if (c>=N) c-=N; 2) Multiple bits can be processed at once; see optimization to "Russian peasant's algorithm" 3) a * b is actually small enough to fit 64-bit unsigned long long without overflow Since ...

2

Since you are looking for nCr for multiple sequential values of n you can make use of the following: (n+1)Cr = (n+1)! / ((r!)*(n+1-r)!) (n+1)Cr = n!*(n+1) / ((r!)*(n-r)!*(n+1-r)) (n+1)Cr = n! / ((r!)*(n-r)!) * (n+1)/(n+1-r) (n+1)Cr = nCr * (n+1)/(n+1-r) This saves you from explicitly calling the factorial function for each i. Furthermore, ...

4

unsigned long long x; unsigned int y, z; x = y*z; The evaluation of the expression y*z is not affected by the context in which it appears. It multiplies two unsigned int values, yielding an unsigned int result. If the mathematical result cannot be represented as an unsigned int value, the result will wrap around. The assignment then implicitly converts ...

5

You are clearly assuming that unsigned int is 32-bit and unsigned long long 64-bit. They don't have to be, be let us assume this. A 64-bit operand that was obtain by converting a 32-bit operand still fits in 32 bits. Thus in y*(unsigned long long)z, where each of the operands is first promoted to unsigned long long, the result is computed as an unsigned ...

3

If one operand is wider than the other, the compiler should be (or behave as if it is) converting both operands to the same size, so casting one to a larger size will produce the correct behaviour. This is specified in the C and C++ standards. The C++11 standard (n3337 draft) has this to say, in chapter five, statement 9: ... if both operands have ...

1

There is no portable way to extract the absolute value of the most negative number as an integer. The ISO C standard says (§6.2.6.2¶2): Each bit that is a value bit shall have the same value as the same bit in the object representation of the corresponding unsigned type (if there are M value bits in the signed type and N in the unsigned type, then M ≤ N ). ...

0

Casting into the next available greater integer type should do it. but you have to use the correspondant abs-variant (in this case llabs(...)) printf("llabs(INT_MIN): %lld\n", llabs((long long int)INT_MIN)); edit: you can check what's the next greater type by comparing INT_MIN to LONG_MIN and LLONG_MIN. Maybe in your case a cast to long will already do ...

0

In C, only the int version exists for the function int abs(int j). You can use another function labs under the header stdlib.h. Its prototype: long int labs(long int j); #include <limits.h> #include <stdio.h> #include <stdlib.h> int main(void) { printf("INT_MAX: %d\n", INT_MAX); printf("INT_MIN: %d\n", INT_MIN); ...

1

The %d conversion specifier in the format string of printf converts the corresponding argument to a signed decimal integer, which in this case, overflows for the int type. C standard specifically mentions that signed integer overflow is undefined behaviour. What you should do is to use %u in the format string. Also, you need to include the headers stdio.h ...

-1

First things first, you have to #include <math.h> to properly use the abs function. Second thing is, if the only thing you want to achieve is to print the absolute value of the INT_MIN defined in limits.h, you can just print it out as an unsigned integer or as a long long integer, like this: printf( "abs(INT_MIN): %u\n", abs( INT_MIN ) ); // %u ...

2

How about printf ("abs(INT_MIN) = %ld", -((long int) INT_MIN)); Or if your long is not longer than an int: printf ("abs(INT_MIN) = %lld", -((long long int) INT_MIN)); Or if you are prepared to accept that abs(INT_MIN) is always INT_MAX + 1: printf ("abs(INT_MIN) = %u", ((unsigned int) INT_MAX ) + 1 );

2

INT_MAX + INT_MIN is always defined because adding two numbers of opposite sign can never overflow. To answer your question as precisely as possible, the C standard mandates either 2's complement, 1's complement or sign-magnitude representation. (C11 6.2.6.2:2). The int type may have padding bits, but the sign and value bits are in any case used to ...

1

You are guaranteed that INT_MIN is at most -32767 and INT_MAX at least 32767. So INT_MAX-1 is always a valid int. INT_MAX + INT_MIN is then also always defined.

1

The C specification requires INT_MIN to be -32767 or less, and INT_MAX to be 32767 or more. As nearly as I can tell, no further guarantees are made. Page 22: http://www.open-std.org/jtc1/sc22/wg14/www/docs/n1124.pdf

0

No. The value of variable is not always negative in case of overflow. With signed integers, C11dr §3.7.1 3 undefined behavior "An example of undefined behavior is the behavior on integer overflow." so there is no test to do after overflow that is certain to work across compilers and platforms. Detect potential overflow before it can happen. int T = 0; ...

-1

Couldn't this problem be converted to K^T <= (M + N - 1) / N? As far as overflow detection goes, normally addition and subtraction are performed as if the numbers were unsigned, with the overflow bit set based on signed math, and the carry / borrow bit set based on unsigned math. For multiplication, the low order of the result is the same for signed or ...

7

From the point of view of the language, the behaviour of signed integer overflow is undefined. Which means anythign could happen - it can be negative, it can be unchanged, the program can crash or it can order pizza online. What will most likely happen in practice depends on the processor architecture on which you're running - so you'd have to consult the ...

-1

Just as in any other situation with signed integers of any length...overflow makes the number negative if and only if the specific bit which is overflowed into the sign bit is on. Meaning if the result of your arithmetic would give you an overflow which, if you were to double the length of your variable word, would leave your current sign bit as off, you ...

1

Up until 128 bits, and assuming you don't need much portability, you may just use built-in types such as uint128_t (supported at least by gcc and clang on x86_64 platforms). If you wish for more portability than this, then 128-bits integers are not standard, so you will need to: Define your own, a pair of 64-bits integer with overload operators would work ...

0

Your statistics will be computed on vectors, which size will not exceed size_t capacity. I think it's enough to detect overflow in your case. I can think of a double conversion of each size, then compare the two products (size_t based product vs double product)

2

It really depends on what you are trying to achieve with your code. If you are later on going to use the value as a size_t (in other words, for sizing a vector, allocating memory, or some such), then you probably should do some checks that it's not overflowing, but store the value as a size_t. You won't be able to use a bigger type anyway, if the purpose ...

0

In your example you're multiplying 100000 and 100000 (rather untypically large values for sizes), where apparently you would want to obtain 10^10 exactly as a result. As a rough calculation based on 2^10 ~= 10^3, divide the 10's exponent by 3 and multiply by 10 to get the number of bits. Now 10*10/3 is roughly 33, which means you need more than 32 bits, ...

2

Have you considered not restricting yourself to a primitive type? If it's important to your application that such huge size_type values are handled, why not create a custom type which holds both original values?

0

IMHO, line 4 is an obvious problem at compilation time, compiler would truncate the value to fit the type, in an implementation defined way (refer to K&R A6.2 Integral Conversions). Yet the compiler does not necessarily run the instructions to detect a potential overflow in implicit integer value conversion, thus the line 5 is simply translated ...

0

when using mpreal, all the numbers with higher than standard precision should be converted into mpreal. A most convenient way is to add quote mark on both sides

2

If one starts by determining which value is larger, there will be certain values of the larger and smaller number which guarantee that overflow can or cannot occur. Assume X is larger; Y is smaller. If X is below 2^31, or if Y is less than 2, overflow is impossible; otherwise, if X is more than 2^62 or Y is not smaller than 2^32, overflow is certain. ...

0

I have a single header at sweet.hpp called conv.hpp. It will test the bounds for all integer types and also allows to and from string casts for integer. short a = to<short>(1337); std::string b = to<std::string>(a); long c = to<long>(b);

0

#include <limits.h> #include <stdlib.h> #include <stdio.h> #include <errno.h> static void check_number(const char *s) { long long v; char *e; v = strtoll(s, &e, 10); if (errno != 0 || *e != '\0' || v < 0 || v > UINT_MAX) { fputs("Nope, that's not gonna fly!\n", stderr); ...

1

The strtoul() function will convert to an unsigned long (which must have at least as much range as unsigned int), and allows you to detect out-of-range values. You can further compare the result against UINT_MAX (from <limits.h>) to determine if it is within range of unsigned int: unsigned long result; errno = 0; result = strtoul(my_array, NULL, ...

0

You could use snprintf to populate a character buffer with UINT_MAX. Then there three possible cases for the length: len(UINT_MAX) > len(your buffer) means that your buffer is ok. len(UINT_MAX) < len(your buffer) means that your buffer is not going to fit. len(UINT_MAX) == len(your buffer) means that you use strcmp to compare the two. Where ...

0

You can use std::strtol or std::strtoll and check their return values: Note: As these two functions tend to convert it to a long/long long, you may also need to check the return value is larger than UINT_MAX if successfully.

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