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src: get rid of fp arithmetic in ParseIPv4Host #46326
src: get rid of fp arithmetic in ParseIPv4Host #46326
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Even though most compiler should not actually emit FPU instructions, it is unnecessary to use floating-point arithmetic for powers of 2. Also change some signed counters to unsigned integers.
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uint32_t val = 0; | ||
uint64_t numbers[4]; | ||
int tooBigNumbers = 0; | ||
unsigned int tooBigNumbers = 0; |
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Out of curiosity, how does someone choose between unsigned int
and uint32_t
?
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Taste, basically. There's no difference unless you're targeting Watcom C++ for DOS, where sizeof(int) == 2
.
Of course Real Programmers(TM) don't care for repeating themselves and just write unsigned
without the int
.
This method is really quite something. Tobias cleans it up but it still looks super complicated. The code below is untested and off the cuff but I think that is what ParseIPv4Host's logic reduces to. The only thing I'm not completely sure about is whether e.g. http://00000000000000000000/
(over 19 chars) is considered a valid input.
if (length > 19) return; // max in octal or hexadecimal
unsigned a, b, c, d, v, ndots = 0;
char s[20];
memcpy(s, input, length);
s[length] = '\0';
for (char* p = s; p = strchr(p, '.'); p++, ndots++);
switch (ndots) {
default:
return;
case 0:
if (1 != sscanf(s, "%u", &v)) return;
break;
case 1:
if (2 != sscanf(s, "%u.%u", &a, &b)) return;
if (a > 255 || b > 0xFFFFFF) return;
v = a << 24 | b;
break;
case 2:
if (3 != sscanf(s, "%u.%u.%u", &a, &b, &c)) return;
if (a > 255 || b > 255 || c > 0xFFFF) return;
v = a << 24 | b << 16 | c;
break;
case 3:
if (4 != sscanf(s, "%u.%u.%u.%u", &a, &b, &c, &d)) return;
if (a > 255 || b > 255 || c > 255 || d > 255) return;
v = a << 24 | b << 16 | c << 8 | d;
break;
}
// parse okay, address in |v|
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tl;dr: personally, I read unsigned int
as "some smallish non-negative integer", whereas uint32_t
makes me question why this variable has to be exactly 32 bits.
Ad-hoc thought process:
Let's assume that there is no obvious type with better semantics for this use case (e.g., size_t
). Otherwise, that type should likely be used instead.
❌ If the variable must have the same size across all platforms, uint32_t
is the logical choice (even though ILP32, LLP64, and LP64 always use 32-bit unsigned int
anyway, and only more exotic architectures such as ILP64 or SILP64 deviate).
❌ If the algorithm requires or benefits from a specific size, then uint32_t
is again the logical choice. This is particularly important if the algorithm relies on unsigned integer overflows (which are well-defined, unlike signed overflows).
❌ If the use case requires a fixed minimum size, then uint_fast32_t
can be useful. However, the implementation might end up quietly relying on a specific type underlying uint_fast32_t
.
- 64-bit architectures are likely to use 64-bit types for
uint_fast32_t
. The implementation might store values exceeding 32 bits in this variable, which will break if anyone tries to use the code on an architecture that uses a 32-bit type foruint_fast32_t
. - Conversely, if an architecture uses a 32-bit type for
uint_fast32_t
, then assigning auint_fast32_t
value to a 32-bit variable works, but it will break if anyone tries to use the code on an architecture that uses a 64-bit type foruint_fast32_t
.
❌ If the variable is mostly used to interact with some library, the type should match whatever the library uses. This is often true for OpenSSL, which for historic reasons frequently uses signed int
values instead of semantically more appropriate types.
✔️ If none of that is true, and if the 16-bit minimum size of unsigned int
is clearly sufficient, then unsigned int
works just fine. Within Node.js, we can even rely on 32-bit unsigned int
, but that's not necessarily true in general, e.g., on AVR.
Of course, following this argument, unsigned short
would work just as well since it is also guaranteed to have a minimum size of 16 bits. However, aside from the (potentially) smaller size when allocating large arrays (e.g., unsigned short[16 * 1024]
may be smaller than unsigned int[16 * 1024]
), unsigned short
has no benefit over unsigned int
. It may even be slower since modern CPUs prefer sizeof(unsigned int)
or sizeof(unsigned long)
registers, and may have to mask the upper parts of those registers for computations on unsigned short
. In fact, uint_fast16_t
usually is either the same as uint32_t
or uint64_t
.
Regardless, what is important to me is the signedness of these variables. I know that this is not a widespread opinion, but to me, "signedness correctness" is almost as important as const correctness.
Landed in 8ba54e5 |
Even though most compiler should not actually emit FPU instructions, it is unnecessary to use floating-point arithmetic for powers of 2. Also change some signed counters to unsigned integers. PR-URL: #46326 Reviewed-By: Yagiz Nizipli <[email protected]> Reviewed-By: Luigi Pinca <[email protected]> Reviewed-By: James M Snell <[email protected]>
Even though most compiler should not actually emit FPU instructions, it is unnecessary to use floating-point arithmetic for powers of 2. Also change some signed counters to unsigned integers. PR-URL: #46326 Reviewed-By: Yagiz Nizipli <[email protected]> Reviewed-By: Luigi Pinca <[email protected]> Reviewed-By: James M Snell <[email protected]>
Even though most compiler should not actually emit FPU instructions, it is unnecessary to use floating-point arithmetic for powers of 2. Also change some signed counters to unsigned integers. PR-URL: #46326 Reviewed-By: Yagiz Nizipli <[email protected]> Reviewed-By: Luigi Pinca <[email protected]> Reviewed-By: James M Snell <[email protected]>
Even though most compiler should not actually emit FPU instructions, it is unnecessary to use floating-point arithmetic for powers of 2. Also change some signed counters to unsigned integers. PR-URL: #46326 Reviewed-By: Yagiz Nizipli <[email protected]> Reviewed-By: Luigi Pinca <[email protected]> Reviewed-By: James M Snell <[email protected]>
Even though most compiler should not actually emit FPU instructions, it is unnecessary to use floating-point arithmetic for powers of 2.
Also change some signed counters to unsigned integers.