Hex
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Function: string hex(integer value);
Returns the hexadecimal nybbles of the signed integer value in order. Specifically returns the nybbles from most to least significant, starting with the first nonzero nybble, folding every nybble to lower case, and beginning with the nonnegative prefix "0x" or the negative prefix "-0x".
Parameters:
| • integer | value | – | signed value to be expressed as signed hex |
Note: Results with eight nybbles begin always with one of the positive signed nybbles 1 2 3 4 5 6 7, never with a zero or unsigned nybble 0 8 9 A B C D E F.
Caution: This page was a work in progress as of 2007-10. The specification, the implementations, the demo, and the sample results may not yet be totally consistent. See the discussion tab.
Implementations
Below are several different versions of the same two functions, each has been optimized with a different use case. These use cases are titled with the common programing goals they highlight: Design Conformance, Readability, Speed and Size. Unfortunately with LSL it is typically very difficult if not impossible to write code that embodies all of these design goals but it is possible to achieve several of them.
The design specification only specifies one function with a specific interface, implementations that do not meet that requirement are not marked as Design Conforming.
Design Conforming & Readability
You should feel this code is easy to review, and modify. Upon review it is easy to see this code conforms to the specification and is easy to read. Additionally the comments instruct the user on how to substitute the easy-to-read upper case A B C D E F nybbles of IBM style for the easy-to-type lower case a b c d e f nybbles of AT&T style. The cost of this readability and easy of use is that the code runs substantially slower and has a larger memory footprint. Every other implementation runs faster then this one.
// http://wiki.secondlife.com/wiki/hex
string XDIGITS = "0123456789abcdef"; // could be "0123456789ABCDEF"
string bits2nybbles(integer bits)
{
string nybbles = "";
while (bits)
{
integer lsbs = bits & 0xF;
string nybble = llGetSubString(XDIGITS, lsbs, lsbs);
nybbles = nybble + nybbles;
bits = bits >> 4; // discard the least significant bits at right
bits = bits & 0xfffFFFF; // discard the sign bits at left
}
return nybbles;
}
string hex(integer value)
{
if (value < 0)
{
return "-0x" + bits2nybbles(-value);
}
else if (value == 0)
{
return "0x0"; // bits2nybbles(value) == "" when (value == 0)
}
else // if (value > 0)
{
return "0x" + bits2nybbles(value);
}
}
LSO Size: 351 bytes
Loop Cost: 2 variables, 124 bytes
Design Conforming & Speed
In this implementation the readability and size have been scarified for speed. At execution, from call to return the fewest number of operators are executed, specifically the loop has been setup to use the fewest number of operators per iteration. In the double function category, this is the fastest implementation.
// http://wiki.secondlife.com/wiki/hex
string XDIGITS = "0123456789abcdef"; // could be "0123456789ABCDEF"
string hexu(integer bits)
{
integer index = (bits & 0xF);
string nybbles = llGetSubString(XDIGITS, index, index);
if ((bits = (0xfffFFFF & (bits >> 4))))
{
do
{
nybbles = llGetSubString(XDIGITS, index = (bits & 0xF), index) + nybbles;
} while ((bits = (bits >> 4)));
}
return "0x" + nybbles;
}
string hex(integer value)
{
//saves one byte over "value < 0" and is faster.
if (value & 0x80000000) return "-" + hexu(-value);
return hexu(value);
}
LSO Size: 341 bytes
Loop Cost: 0 variables, 81 bytes
Design Conforming & Size
Here is a size optimized implementation. It has a reduced memory footprint but is slower then a Speed implementations.
// http://wiki.secondlife.com/wiki/hex
string hexu(integer bits)
{
string nybbles = "";
do
{
integer index = bits & 0xF;
nybbles = llGetSubString("0123456789abcdef", index, index) + nybbles;
} while ((bits = (0xfffFFFF & (bits >> 4))));
return "0x" + nybbles;
}
string hex(integer value)
{
//saves one byte over "value < 0" and is faster.
if (value & 0x80000000) return "-" + hexu(-value);
return hexu(value);
}
LSO Size: 254 bytes
Loop Cost: 1 variable, 105 bytes
Design Conforming & Size - Signed Only
Here is an optimized implementation that only uses a single function, this provides an additional reduction to the memory footprint.
// http://wiki.secondlife.com/wiki/hex
string hex(integer value)
{
string lead = "0x";
if(value & 0x80000000)
{//saves one byte over "value < 0" and is faster.
lead = "-0x";
value = -value;
}
string nybbles = "";
do
{
integer index = value & 0xF;
nybbles = llGetSubString("0123456789abcdef", index, index) + nybbles;
} while ((value = (0xfffFFFF & (value >> 4))));
return lead + nybbles;
}
LSO Size: 201 bytes
Loop Cost: 1 variables, 105 bytes
Size
Here is a version where the calling interface has been changed to allow for the two functions to be merged. This merge allows for a considerable savings in bytecode. This savings evaporates if the function is explicitly called from more than 10 places in the script (as compared to the double function size implementation). This of course assumes you need both sets of functionality.
// http://wiki.secondlife.com/wiki/hex
string hex(integer value, integer signed)
{
string lead = "0x";
if((value & 0x80000000) && signed)
{//saves one byte over "value < 0" and is faster.
lead = "-0x";
value = -value;
}
string nybbles = "";
do //variable recycling is ugly but it saves bytecode
nybbles = llGetSubString("0123456789abcdef", signed = (value & 0xF), signed) + nybbles;
while ((value = (0xfffFFFF & (value >> 4))));
return lead + nybbles;
}
LSO Size: 204 bytes
Loop Cost: 0 variables, 100 bytes
Demo
This demo script shows some interesting test cases for the hex function and the permission masks of the script.
Code:
default
{
state_entry()
{
llOwnerSay("Hello");
llOwnerSay(hex(0) + " == 0");
llOwnerSay(hex(0x00FEDC00 & -0x00FEDC00) + " == (0x00FEDC00 & -0x00FEDC00)");
llOwnerSay(hex(1 << 30) + " == (1 << 30)");
llOwnerSay(hex(0x80000000) + " == 0x80000000");
llOwnerSay(hex(0xFEDC9876) + " == 0xFEDC9876");
llOwnerSay(hex(-1) + " == -1");
llOwnerSay(hex(0x123456789) + " == 0x123456789");
llOwnerSay("OK");
llOwnerSay("Hello again");
string item = llGetScriptName();
llOwnerSay(hex(llGetInventoryPermMask(item, MASK_BASE)) + " as base");
llOwnerSay(hex(llGetInventoryPermMask(item, MASK_OWNER)) + " by owner");
llOwnerSay(hex(llGetInventoryPermMask(item, MASK_GROUP)) + " by group");
llOwnerSay(hex(llGetInventoryPermMask(item, MASK_EVERYONE)) + " by anyone");
llOwnerSay(hex(llGetInventoryPermMask(item, MASK_NEXT)) + " by next owner");
llOwnerSay("aka " + (string) llGetInventoryPermMask(item, MASK_NEXT));
llOwnerSay("OK");
}
}
Sample Results:
Hello 0x0 == 0 0x400 == (0x00FEDC00 & -0x00FEDC00) 0x40000000 == (1 << 30) -0x80000000 == 0x80000000 -0x123678a == 0xFEDC9876 -0x1 == -1 -0x1 == 0x123456789 OK Hello again 0x7fffffff as base 0x7fffffff by owner 0x0 by group 0x0 by anyone 0x82000 by next owner aka 532480 OK
Note:
If you are using an implementation that doesn't conform to the specification the demo script may not compile or give the same results.
Design Rationale
The first few implementations we present do conform to our specification.
Our specification requires exactly the same results as the hex function of the Python scripting language.
This specification reproduces how hex integer literals often appear in LSL script, conforming to such arbitrary and traditional AT&T C conventions as:
- return lower case a b c d e f rather than upper case A B C D E F,
- return a signed 31-bit result if negative, rather than an unsigned 32-bit result,
- omit the leading quads of zeroed bits, except returns "0x0" rather than "0x" when the result is zero,
- return a meaningless "0" before the "x", as LSL and C compilers require,
- return the "x" on the left as in LSL and C, not the "h" on the right as in Assembly code, and
- return the nybbles listed from most to least significant as in English, not listed from least to most significant as in Arabic.
Brief doc for the Python hex function appears buried deep within http://docs.python.org/lib/built-in-funcs.html
Disputes over the detailed specification of the Python hex function appear buried deep within http://www.python.org/dev/peps/pep-0237/
There are multiple implementations because LSL is inadequate to produce a version that is optimal in the majority of popular use cases.