In code created by Apple, there is this line:
CMTimeMakeWithSeconds( newDurationSeconds, 1000*1000*1000 )
Is there any reason to express
1000^3 for that matter?
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One reason to declare constants in a multiplicative way is to improve readability, while the run-time performance is not affected. Also, to indicate that the writer was thinking in a multiplicative manner about the number.
double memoryBytes = 1024 * 1024 * 1024;
It's clearly better than:
double memoryBytes = 1073741824;
as the latter doesn't look, at first glance, the third power of 1024.
As Amin Negm-Awad mentioned, the
^ operator is the binary
XOR. Many languages lack the built-in, compile-time exponentiation operator, hence the multiplication.
The result of
1000^3 is 1003.
^ is the bit-XOR operator.
Even it does not deal with the Q itself, I add a clarification.
x^y does not always evaluate to
x+y as it does in the questioner's example. You have to xor every bit. In the case of the example:
1111101000₂ (1000₁₀) 0000000011₂ (3₁₀) 1111101011₂ (1003₁₀)
1111101001₂ (1001₁₀) 0000000011₂ (3₁₀) 1111101010₂ (1002₁₀)
There are reasons not to use
1000 * 1000 * 1000.
1000 * 1000 overflows. So using
1000 * 1000 * 1000 reduces portability.
int, the following first line of code overflows.
long long Duration = 1000 * 1000 * 1000 * 1000; // overflow long long Duration = 1000000000000; // no overflow, hard to read
Suggest that the lead value matches the type of the destination for readability, portability and correctness.
double Duration = 1000.0 * 1000 * 1000; long long Duration = 1000LL * 1000 * 1000 * 1000;
Also could simple use
e notation for values that are exactly representable as a
double. Of course this leads to knowing if
double can exactly represent the whole number value - something of concern with values greater than 1e9. (See
long Duration = 1000000000; // vs. long Duration = 1e9;
Placing commas and spaces between the zeros (
1 000 000 000 or
1,000,000,000) would produce a syntax error, and having
1000000000 in the code makes it hard to see exactly how many zeros are there.
1000*1000*1000 makes it apparent that it's 10^9, because our eyes can process the chunks more easily. Also, there's no runtime cost, because the compiler will replace it with the constant
For readability. For comparison, Java supports
_ in numbers to improve readability (first proposed by Stephen Colebourne as a reply to Derek Foster's PROPOSAL: Binary Literals for Project Coin/JSR 334) . One would write
In roughly chronological order, from oldest support to newest:
"(1)1111 1111"(apparently not for decimal values, only for bitstrings representing binary, quartal, octal or hexadecimal values)
It's a relatively new feature for languages to realize they ought to support (and then there's Perl). As in chux@'s excellent answer,
1000*1000... is a partial solution but opens the programmer up to bugs from overflowing the multiplication even if the final result is a large type.
Might be simpler to read and get some associations with the
From technical aspect I guess there is no difference between the direct number or multiplication. The compiler will generate it as constant billion number anyway.
If you speak about objective-c, then
1000^3 won't work because there is no such syntax for pow (it is xor). Instead,
pow() function can be used. But in that case, it will not be optimal, it will be a runtime function call not a compiler generated constant.
Another way to achieve a similar effect in C for decimal numbers is to use literal floating point notation -- so long as a double can represent the number you want without any loss of precision.
IEEE 754 64-bit double can represent any non-negative integer <= 2^53 without problem. Typically, long double (80 or 128 bits) can go even further than that. The conversions will be done at compile time, so there is no runtime overhead and you will likely get warnings if there is an unexpected loss of precision and you have a good compiler.
long lots_of_secs = 1e9;