Obtaining range of bits its from a given no - c++11

I am using the following function to extract n bits from a number. I got this function from here. For convenience I am posting it here. I would like to obtain bits from 0 to 9 and then in another statement bits 10 to 15. I am passing in 1033. I get the correct value of bits 0 to 9 but incorrect value for 10 to 15. I should get a 1 instead i am getting 1024 any suggestions ?
unsigned createMask(unsigned a, unsigned b)
{
unsigned r = 0;
for (unsigned i = a; i <= b; i++)
r |= 1 << i;
return r;
}
Now i have this
unsigned short langId = 1033 ;// 10000001001
unsigned primary = createMask(0,9) & langId; //gives 9 correct
unsigned sec = createMask(10,15) & langId; //gives 1024 incorrect should be 1

The bits of sec that you've set are still in the 10-15 bit positions. You need to shift them back towards the start. Otherwise you have a single 1 set at position 10 and 210 is giving your answer of 1024
sec >> 10
Demo

Related

Why am I getting negative integer after adding two positive 16 bit integers?

I am a newbie to golang, actually, I am new to type based programming. I have only knowledge of JS.
While going through simple examples in golang tutorials. I found that adding a1 + a2 provides a negative integer value?
var a1 int16 = 127
var a2 int16 = 32767
var rr int16 = a1 + a2
fmt.Println(rr)
Result:
-32642
Excepted:
The compiler will throw an error as a exceeded the int16 max.
( OR ) GO automatically convert the int16 to int32.
32,894
Can you guys explain why it is showing -32642.
This is the result of Integer Overflow behaving as defined in the specification.
You don't see your expected results, because
Overflow happens at runtime, not compile time.
Go is statically typed.
32,894 is greater than the max value representable by an int16.
It’s very simple.
The 16 bit integer maps the positive part I 0 - 32767 (0x0000, 0x7FFF) and the negative part from 0x8000 (−32768) to 0xFFFF (-1).
For example 0 - 1 = -1 and it’s store as 0xFFFF.
Now in your specific case: 32767 + 127.
You overflow because 32767 is the max value for a signed 16 bit integer, but, if you force the addition 0x7FFF + 7F = 807E and convert 807E to signed 16 bit integer you obtain -32642.
You can better understand here: Signed number representations
Aditionally, check these Math Constants:
const (
MaxInt8 = 1<<7 - 1
MinInt8 = -1 << 7
MaxInt16 = 1<<15 - 1
MinInt16 = -1 << 15
MaxInt32 = 1<<31 - 1
MinInt32 = -1 << 31
MaxInt64 = 1<<63 - 1
MinInt64 = -1 << 63
MaxUint8 = 1<<8 - 1
MaxUint16 = 1<<16 - 1
MaxUint32 = 1<<32 - 1
MaxUint64 = 1<<64 - 1
)
And check the human version of these values here

Find the closest integer with same weight O(1)

I am solving this problem:
The count of ones in binary representation of integer number is called the weight of that number. The following algorithm finds the closest integer with the same weight. For example, for 123 (0111 1011)₂, the closest integer number is 125 (0111 1101)₂.
The solution for O(n)
where n is the width of the input number is by swapping the positions of the first pair of consecutive bits that differ.
Could someone give me some hints for solving in it in O(1) runtime and space ?
Thanks
As already commented by ajayv this cannot really be done in O(1) as the answer always depends on the number of bits the input has. However, if we interpret the O(1) to mean that we have as an input some primitive integer data and all the logic and arithmetic operations we perform on that integer are O(1) (no loops over the bits), the problem can be solved in constant time. Of course, if we changed from 32bit integer to 64bit integer the running time would increase as the arithmetic operations would take longer on hardware.
One possible solution is to use following functions. The first gives you a number where only the lowest set bit of x is set
int lowestBitSet(int x){
( x & ~(x-1) )
}
and the second the lowest bit not set
int lowestBitNotSet(int x){
return ~x & (x+1);
}
If you work few examples of these on paper you see how they work.
Now you can find the bits you need to change using these two functions and then use the algorithm you already described.
A c++ implementation (not checking for cases where there are no answer)
unsigned int closestInt(unsigned int x){
unsigned int ns=lowestBitNotSet(x);
unsigned int s=lowestBitSet(x);
if (ns>s){
x|=ns;
x^=ns>>1;
}
else{
x^=s;
x|=s>>1;
}
return x;
}
To solve this problem in O(1) time complexity it can be considered that there are two main cases:
1) When LSB is '0':
In this case, the first '1' must be shifted with one position to the right.
Input : "10001000"
Out ::: "10000100"
2) When LSB is '1':
In this case the first '0' must be set to '1', and first '1' must be set to '0'.
Input : "10000111"
Out ::: "10001110"
The next method in Java represents one solution.
private static void findClosestInteger(String word) { // ex: word = "10001000"
System.out.println(word); // Print initial binary format of the number
int x = Integer.parseInt(word, 2); // Convert String to int
if((x & 1) == 0) { // Evaluates LSB value
// Case when LSB = '0':
// Input: x = 10001000
int firstOne = x & ~(x -1); // get first '1' position (from right to left)
// firstOne = 00001000
x = x & (x - 1); // set first '1' to '0'
// x = 10000000
x = x | (firstOne >> 1); // "shift" first '1' with one position to right
// x = 10000100
} else {
// Case when LSB = '1':
// Input: x = 10000111
int firstZero = ~x & ~(~x - 1); // get first '0' position (from right to left)
// firstZero = 00001000
x = x & (~1); // set first '1', which is the LSB, to '0'
// x = 10000110
x = x | firstZero; // set first '0' to '1'
// x = 10001110
}
for(int i = word.length() - 1; i > -1 ; i--) { // print the closest integer with same weight
System.out.print("" + ( ( (x & 1 << i) != 0) ? 1 : 0) );
}
}
The problem can be viewed as "which differing bits to swap in a bit representation of a number, so that the resultant number is closest to the original?"
So, if we we're to swap bits at indices k1 & k2, with k2 > k1, the difference between the numbers would be 2^k2 - 2^k1. Our goal is to minimize this difference. Assuming that the bit representation is not all 0s or all 1s, a simple observation yields that the difference would be least if we kept |k2 - k1| as minimum. The minimum value can be 1. So, if we're able to find two consecutive different bits, starting from the least significant bit (index = 0), our job is done.
The case where bits starting from Least Significant Bit to the right most set bit are all 1s
k2
|
7 6 5 4 3 2 1 0
---------------
n: 1 1 1 0 1 0 1 1
rightmostSetBit: 0 0 0 0 0 0 0 1
rightmostNotSetBit: 0 0 0 0 0 1 0 0 rightmostNotSetBit > rightmostSetBit so,
difference: 0 0 0 0 0 0 1 0 i.e. rightmostNotSetBit - (rightmostNotSetBit >> 1):
---------------
n + difference: 1 1 1 0 1 1 0 1
The case where bits starting from Least Significant Bit to the right most set bit are all 0s
k2
|
7 6 5 4 3 2 1 0
---------------
n: 1 1 1 0 1 1 0 0
rightmostSetBit: 0 0 0 0 0 1 0 0
rightmostNotSetBit: 0 0 0 0 0 0 0 1 rightmostSetBit > rightmostNotSetBit so,
difference: 0 0 0 0 0 0 1 0 i.e. rightmostSetBit -(rightmostSetBit>> 1)
---------------
n - difference: 1 1 1 0 1 0 1 0
The edge case, of course the situation where we have all 0s or all 1s.
public static long closestToWeight(long n){
if(n <= 0 /* If all 0s */ || (n+1) == Integer.MIN_VALUE /* n is MAX_INT */)
return -1;
long neg = ~n;
long rightmostSetBit = n&~(n-1);
long rightmostNotSetBit = neg&~(neg-1);
if(rightmostNotSetBit > rightmostSetBit){
return (n + (rightmostNotSetBit - (rightmostNotSetBit >> 1)));
}
return (n - (rightmostSetBit - (rightmostSetBit >> 1)));
}
Attempted the problem in Python. Can be viewed as a translation of Ari's solution with the edge case handled:
def closest_int_same_bit_count(x):
# if all bits of x are 0 or 1, there can't be an answer
if x & sys.maxsize in {sys.maxsize, 0}:
raise ValueError("All bits are 0 or 1")
rightmost_set_bit = x & ~(x - 1)
next_un_set_bit = ~x & (x + 1)
if next_un_set_bit > rightmost_set_bit:
# 0 shifted to the right e.g 0111 -> 1011
x ^= next_un_set_bit | next_un_set_bit >> 1
else:
# 1 shifted to the right 1000 -> 0100
x ^= rightmost_set_bit | rightmost_set_bit >> 1
return x
Similarly jigsawmnc's solution is provided below:
def closest_int_same_bit_count(x):
# if all bits of x are 0 or 1, there can't be an answer
if x & sys.maxsize in {sys.maxsize, 0}:
raise ValueError("All bits are 0 or 1")
rightmost_set_bit = x & ~(x - 1)
next_un_set_bit = ~x & (x + 1)
if next_un_set_bit > rightmost_set_bit:
# 0 shifted to the right e.g 0111 -> 1011
x += next_un_set_bit - (next_un_set_bit >> 1)
else:
# 1 shifted to the right 1000 -> 0100
x -= rightmost_set_bit - (rightmost_set_bit >> 1)
return x
Java Solution:
//Swap the two rightmost consecutive bits that are different
for (int i = 0; i < 64; i++) {
if ((((x >> i) & 1) ^ ((x >> (i+1)) & 1)) == 1) {
// then swap them or flip their bits
int mask = (1 << i) | (1 << i + 1);
x = x ^ mask;
System.out.println("x = " + x);
return;
}
}
static void findClosestIntWithSameWeight(uint x)
{
uint xWithfirstBitSettoZero = x & (x - 1);
uint xWithOnlyfirstbitSet = x & ~(x - 1);
uint xWithNextTofirstBitSet = xWithOnlyfirstbitSet >> 1;
uint closestWeightNum = xWithfirstBitSettoZero | xWithNextTofirstBitSet;
Console.WriteLine("Closet Weight for {0} is {1}", x, closestWeightNum);
}
Code in python:
def closest_int_same_bit_count(x):
if (x & 1) != ((x >> 1) & 1):
return x ^ 0x3
diff = x ^ (x >> 1)
rbs = diff & ~(diff - 1)
i = int(math.log(rbs, 2))
return x ^ (1 << i | 1 << i + 1)
A great explanation of this problem can be found on question 4.4 in EPI.
(Elements of Programming Interviews)
Another place would be this link on geeksforgeeks.org if you don't own the book.
(Time complexity may be wrong on this link)
Two things you should keep in mind here is (Hint if you're trying to solve this for yourself):
You can use x & (x - 1) to clear the lowest set-bit (not to get confused with LSB - least significant bit)
You can use x & ~(x - 1) to get/extract the lowest set bit
If you know the O(n) solution you know that we need to find the index of the first bit that differs from LSB.
If you don't know what the LBS is:
0000 0000
^ // it's bit all the way to the right of a binary string.
Take the base two number 1011 1000 (184 in decimal)
The first bit that differs from LSB:
1011 1000
^ // this one
We'll record this as K1 = 0000 1000
Then we need to swap it with the very next bit to the right:
0000 1000
^ // this one
We'll record this as K2 = 0000 0100
Bitwise OR K1 and K2 together and you'll get a mask
mask = K1 | k2 // 0000 1000 | 0000 0100 -> 0000 1100
Bitwise XOR the mask with the original number and you'll have the correct output/swap
number ^ mask // 1011 1000 ^ 0000 1100 -> 1011 0100
Now before we pull everything together we have to consider that fact that the LSB could be 0001, and so could a bunch of bits after that 1000 1111. So we have to deal with the two cases of the first bit that differs from the LSB; it may be a 1 or 0.
First we have a conditional that test the LSB to be 1 or 0: x & 1
IF 1 return x XORed with the return of a helper function
This helper function has a second argument which its value depends on whether the condition is true or not. func(x, 0xFFFFFFFF) // if true // 0xFFFFFFFF 64 bit word with all bits set to 1
Otherwise we'll skip the if statement and return a similar expression but with a different value provided to the second argument.
return x XORed with func(x, 0x00000000) // 64 bit word with all bits set to 0. You could alternatively just pass 0 but I did this for consistency
Our helper function returns a mask that we are going to XOR with the original number to get our output.
It takes two arguments, our original number and a mask, used in this expression:
(x ^ mask) & ~((x ^ mask) - 1)
which gives us a new number with the bit at index K1 always set to 1.
It then shifts that bit 1 to the right (i.e index K2) then ORs it with itself to create our final mask
0000 1000 >> 1 -> 0000 0100 | 0001 0000 -> 0000 1100
This all implemented in C++ looks like:
unsigned long long int closestIntSameBitCount(unsigned long long int n)
{
if (n & 1)
return n ^= getSwapMask(n, 0xFFFFFFFF);
return n ^= getSwapMask(n, 0x00000000);
}
// Helper function
unsigned long long int getSwapMask(unsigned long long int n, unsigned long long int mask)
{
unsigned long long int swapBitMask = (n ^ mask) & ~((n ^ mask) - 1);
return swapBitMask | (swapBitMask >> 1);
}
Keep note of the expression (x ^ mask) & ~((x ^ mask) - 1)
I'll now run through this code with my example 1011 1000:
// start of closestIntSameBitCount
if (0) // 1011 1000 & 1 -> 0000 0000
// start of getSwapMask
getSwapMask(1011 1000, 0x00000000)
swapBitMask = (x ^ mask) & ~1011 0111 // ((x ^ mask) - 1) = 1011 1000 ^ .... 0000 0000 -> 1011 1000 - 1 -> 1011 0111
swapBitMask = (x ^ mask) & 0100 1000 // ~1011 0111 -> 0100 1000
swapBitMask = 1011 1000 & 0100 1000 // (x ^ mask) = 1011 1000 ^ .... 0000 0000 -> 1011 1000
swapBitMask = 0000 1000 // 1011 1000 & 0100 1000 -> 0000 1000
return swapBitMask | 0000 0100 // (swapBitMask >> 1) = 0000 1000 >> 1 -> 0000 0100
return 0000 1100 // 0000 1000 | 0000 0100 -> 0000 11000
// end of getSwapMask
return 1011 0100 // 1011 1000 ^ 0000 11000 -> 1011 0100
// end of closestIntSameBitCount
Here is a full running example if you would like compile and run it your self:
#include <iostream>
#include <stdio.h>
#include <bitset>
unsigned long long int closestIntSameBitCount(unsigned long long int n);
unsigned long long int getSwapMask(unsigned long long int n, unsigned long long int mask);
int main()
{
unsigned long long int number;
printf("Pick a number: ");
std::cin >> number;
std::bitset<64> a(number);
std::bitset<64> b(closestIntSameBitCount(number));
std::cout << a
<< "\n"
<< b
<< std::endl;
}
unsigned long long int closestIntSameBitCount(unsigned long long int n)
{
if (n & 1)
return n ^= getSwapMask(n, 0xFFFFFFFF);
return n ^= getSwapMask(n, 0x00000000);
}
// Helper function
unsigned long long int getSwapMask(unsigned long long int n, unsigned long long int mask)
{
unsigned long long int swapBitMask = (n ^ mask) & ~((n ^ mask) - 1);
return swapBitMask | (swapBitMask >> 1);
}
This was my solution to the problem. I guess #jigsawmnc explains pretty well why we need to have |k2 -k1| to a minimum. So in order to find the closest integer, with the same weight, we would want to find the location where consecutive bits are flipped and then flip them again to get the answer. In order to do that we can shift the number 1 unit. Take the XOR with the same number. This will set bits at all locations where there is a flip. Find the least significant bit for the XOR. This will give you the smallest location to flip. Create a mask for the location and next bit. Take an XOR and that should be the answer. This won't work, if the digits are all 0 or all 1
Here is the code for it.
def variant_closest_int(x: int) -> int:
if x == 0 or ~x == 0:
raise ValueError('All bits are 0 or 1')
x_ = x >> 1
lsb = x ^ x_
mask_ = lsb & ~(lsb - 1)
mask = mask_ | (mask_ << 1)
return x ^ mask
My solution, takes advantage of the parity of the integer. I think the way I got the LSB masks can be simplified
def next_weighted_int(x):
if x % 2 == 0:
lsb_mask = ( ((x - 1) ^ x) >> 1 ) + 1 # Gets a mask for the first 1
x ^= lsb_mask
x |= (lsb_mask >> 1)
return x
lsb_mask = ((x ^ (x + 1)) >> 1 ) + 1 # Gets a mask for the first 0
x |= lsb_mask
x ^= (lsb_mask >> 1)
return x
Just sharing my python solution for this problem:
def same closest_int_same_bit_count(a):
x = a + (a & 1) # change last bit to 0
bit = (x & ~(x-1)) # get last set bit
return a ^ (bit | bit >> 1) # swap set bit with unset bit
func findClosestIntegerWithTheSameWeight2(x int) int {
rightMost0 := ^x & (x + 1)
rightMost1 := x & (-x)
if rightMost0 > 1 {
return (x ^ rightMost0) ^ (rightMost0 >> 1)
} else {
return (x ^ rightMost1) ^ (rightMost1 >> 1)
}
}

CRC Reverse Engineer (Checksum from Machine / PC)

I'm currently looking for on how to determine the CRC produced from the machine to PC (and vice-versa).
The devices are communicating using serial communication or RS232 cable.
I do only have data to be able for us to create a program to be used for both devices.
The data given was from my boss and the program was corrupted. So we are trying for it to work out.
I hope everyone can help.
Thanks :)
The sequence to use for the CRC calculation in your protocol is the ASCII string
starting from the first printing character (e.g. the 'R' from REQ)
until and including the '1E' in the calculation.
It's a CRC with the following specs according to our CRC calculator
CRC:16,1021,0000,0000,No,No
which means:
CRC width: 16 bit (of course)
polynomial: 1021 HEX (truncated CRC polynomial)
init value: 0000
final Xor applied: 0000
reflectedInput: No
reflectedOutput: No`
(If 'init value' were FFFF, it would be a "16 bit width CRC as designated by CCITT").
See also the Docklight CRC glossary and the Boost CRC library on what the CRC terms mean plus sample code.
What I did is to write a small script that tries out the popular 16 bit CRCs on varying parts of the first simple "REQ=INI" command, and see if I end up with a sum of 4255. This failed, but instead of going a full brute force with trying all sorts of polynoms, I assumed that it was maybe just an oddball / flawed implementation of the known standards, and indeed succeeded with a variation of the CRC-CCITT.
Heres is some slow & easy C code (not table based!) to calculate all sorts of CRCs:
// Generic, not table-based CRC calculation
// Based on and credits to the following:
// CRC tester v1.3 written on 4th of February 2003 by Sven Reifegerste (zorc/reflex)
unsigned long reflect (unsigned long crc, int bitnum) {
// reflects the lower 'bitnum' bits of 'crc'
unsigned long i, j=1, crcout=0;
for (i=(unsigned long)1<<(bitnum-1); i; i>>=1) {
if (crc & i) crcout|=j;
j<<= 1;
}
return (crcout);
}
calcCRC(
const int width, const unsigned long polynominal, const unsigned long initialRemainder,
const unsigned long finalXOR, const int reflectedInput, const int reflectedOutput,
const unsigned char message[], const long startIndex, const long endIndex)
{
// Ensure the width is in range: 1-32 bits
assert(width >= 1 && width <= 32);
// some constant parameters used
const bool b_refInput = (reflectedInput > 0);
const bool b_refOutput = (reflectedOutput > 0);
const unsigned long crcmask = ((((unsigned long)1<<(width-1))-1)<<1)|1;
const unsigned long crchighbit = (unsigned long)1<<(width-1);
unsigned long j, c, bit;
unsigned long crc = initialRemainder;
for (long msgIndex = startIndex; msgIndex <= endIndex; ++msgIndex) {
c = (unsigned long)message[msgIndex];
if (b_refInput) c = reflect(c, 8);
for (j=0x80; j; j>>=1) {
bit = crc & crchighbit;
crc<<= 1;
if (c & j) bit^= crchighbit;
if (bit) crc^= polynominal;
}
}
if (b_refOutput) crc=reflect(crc, width);
crc^= finalXOR;
crc&= crcmask;
return(crc);
}
With this code and the CRCs specs listed above, I have been able to re-calculate the following three sample CRCs:
10.03.2014 22:20:57.109 [TX] - REQ=INI<CR><LF>
<RS>CRC=4255<CR><LF>
<GS>
10.03.2014 22:20:57.731 [TX] - ANS=INI<CR><LF>
STATUS=0<CR><LF>
<RS>CRC=57654<CR><LF>
<GS>
10.03.2014 22:20:59.323 [TX] - ANS=INI<CR><LF>
STATUS=0<CR><LF>
MID="CTL1"<CR><LF>
DEF="DTLREQ";1025<CR><LF>
INFO=0<CR><LF>
<RS>CRC=1683<CR><LF>
<GS>
I failed on the very complex one with the DEF= parts - probably didn't understand the character sequence correctly.
The Docklight script I used to reverse engineer this:
Sub crcReverseEngineer()
Dim crctypes(7)
crctypes(0) = "CRC:16,1021,FFFF,0000" ' CCITT
crctypes(1) = "CRC:16,8005,0000,0000" ' CRC-16
crctypes(2) = "CRC:16,8005,FFFF,0000" ' CRC-MODBUS
' lets try also some nonstandard variations with different init and final Xor, but stick
' to the known two polynoms.
crctypes(3) = "CRC:16,1021,FFFF,FFFF"
crctypes(4) = "CRC:16,1021,0000,FFFF"
crctypes(5) = "CRC:16,1021,0000,0000"
crctypes(6) = "CRC:16,8005,FFFF,FFFF"
crctypes(7) = "CRC:16,8005,FFFF,0000"
crcString = "06 1C 52 45 51 3D 49 4E 49 0D 0A 1E 43 52 43 3D 30 30 30 30 0D 0A 1D"
For reflectedInOrOut = 0 To 3
For cType = 0 To 7
crcSpec = crctypes(cType) & "," & IIf(reflectedInOrOut Mod 2 = 1, "Yes", "No") & "," & IIf(reflectedInOrOut > 1, "Yes", "No")
For cStart = 1 To 3
For cEnd = 9 To (Len(crcString) + 1) / 3
subDataString = Mid(crcString, (cStart - 1) * 3 + 1, (cEnd - cStart + 1) * 3)
result = DL.CalcChecksum(crcSpec, subDataString, "H")
resultInt = CLng("&h" + Left(result, 2)) * 256 + CLng("&h" + Right(result, 2))
If resultInt = 4255 Then
DL.AddComment "Found it!"
DL.AddComment "sequence: " & subDataString
DL.AddComment "CRC spec: " & crcSpec
DL.AddComment "CRC result: " & result & " (Integer = " & resultInt & ")"
Exit Sub
End If
Next
Next
Next
Next
End Sub
Public Function IIf(blnExpression, vTrueResult, vFalseResult)
If blnExpression Then
IIf = vTrueResult
Else
IIf = vFalseResult
End If
End Function
Hope this helps and I'm happy to provide extra information or clarify details.

To convert RGB 12 bit data to RGB 12 bit packed data

I have some RGB(image) data which is 12 bit. Each R,G,B has 12 bits, total 36 bits.
Now I need to club this 12 bit RGB data into a packed data format. I have tried to mention the packing as below:-
At present I have input data as -
B0 - 12 bits G0 - 12 bits R0 - 12 bits B1 - 12 bits G1 - 12 bits R1 - 12 bits .. so on.
I need to convert it to packed format as:-
Byte1 - B8 (8 bits of B0 data)
Byte2 - G4B4 (remaining 4 bits of B0 data+ first 4 bits of G0)
Byte3 - G8 (remaining 8 bits of G0)
Byte4 - R8 (first 8 bits of R0)
Byte5 - B4R4 (first 4 bits of B1 + last 4 bits of R0)
I have to write these individual bytes to a file in text format. one byte below another.
Similar thing i have to do for a 10 bit RGB input data.
Is there any tool/software to get the conversion of data i am looking to get done.
I am trying to do it in a C program - I am forming a 64 bit from the individual 12 bits of R,G,B (total 36 bits). But after that I am not able to come up with a logic to pick
the necessary bits from a R,G,B data to form a byte stream, and to dump them to a text file.
Any pointers will be helpful.
This is pretty much untested, super messy code I whipped together to give you a start. It's probably not packing the bytes exactly as you want, but you should get the general idea.
Apologies for the quick and nasty code, only had a couple of minutes, hope it's of some help anyway.
#include <stdio.h>
typedef struct
{
unsigned short B;
unsigned short G;
unsigned short R;
} UnpackedRGB;
UnpackedRGB test[] =
{
{0x0FFF, 0x000, 0x0EEE},
{0x000, 0x0FEF, 0xDEF},
{0xFED, 0xDED, 0xFED},
{0x111, 0x222, 0x333},
{0xA10, 0xB10, 0xC10}
};
UnpackedRGB buffer = {0, 0, 0};
int main(int argc, char** argv)
{
int numSourcePixels = sizeof(test)/sizeof(UnpackedRGB);
/* round up to the last byte */
int destbytes = ((numSourcePixels * 45)+5)/10;
unsigned char* dest = (unsigned char*)malloc(destbytes);
unsigned char* currentDestByte = dest;
UnpackedRGB *pixel1;
UnpackedRGB *pixel2;
int ixSource;
for (ixSource = 0; ixSource < numSourcePixels; ixSource += 2)
{
pixel1 = &test[ixSource];
pixel2 = ((ixSource + 1) < numSourcePixels ? &test[ixSource] : &buffer);
*currentDestByte++ = (0x0FF) & pixel1->B;
*currentDestByte++ = ((0xF00 & pixel1->B) >> 8) | (0x0F & pixel1->G);
*currentDestByte++ = ((0xFF0 & pixel1->G) >> 4);
*currentDestByte++ = (0x0FF & pixel1->R);
*currentDestByte++ = ((0xF00 & pixel1->R) >> 8) | (0x0F & pixel2->B);
if ((ixSource + 1) >= numSourcePixels)
{
break;
}
*currentDestByte++ = ((0xFF0 & pixel2->B) >> 4);
*currentDestByte++ = (0x0FF & pixel2->G);
*currentDestByte++ = ((0xF00 & pixel2->G) >> 8) | (0x0F & pixel2->R);
*currentDestByte++ = (0xFF0 & pixel2->R);
}
FILE* outfile = fopen("output.bin", "w");
fwrite(dest, 1, destbytes,outfile);
fclose(outfile);
}
Use bitwise & (and), | (or), and shift <<, >> operators.

Counting, reversed bit pattern

I am trying to find an algorithm to count from 0 to 2n-1 but their bit pattern reversed. I care about only n LSB of a word. As you may have guessed I failed.
For n=3:
000 -> 0
100 -> 4
010 -> 2
110 -> 6
001 -> 1
101 -> 5
011 -> 3
111 -> 7
You get the idea.
Answers in pseudo-code is great. Code fragments in any language are welcome, answers without bit operations are preferred.
Please don't just post a fragment without even a short explanation or a pointer to a source.
Edit: I forgot to add, I already have a naive implementation which just bit-reverses a count variable. In a sense, this method is not really counting.
This is, I think easiest with bit operations, even though you said this wasn't preferred
Assuming 32 bit ints, here's a nifty chunk of code that can reverse all of the bits without doing it in 32 steps:
unsigned int i;
i = (i & 0x55555555) << 1 | (i & 0xaaaaaaaa) >> 1;
i = (i & 0x33333333) << 2 | (i & 0xcccccccc) >> 2;
i = (i & 0x0f0f0f0f) << 4 | (i & 0xf0f0f0f0) >> 4;
i = (i & 0x00ff00ff) << 8 | (i & 0xff00ff00) >> 8;
i = (i & 0x0000ffff) << 16 | (i & 0xffff0000) >> 16;
i >>= (32 - n);
Essentially this does an interleaved shuffle of all of the bits. Each time around half of the bits in the value are swapped with the other half.
The last line is necessary to realign the bits so that bin "n" is the most significant bit.
Shorter versions of this are possible if "n" is <= 16, or <= 8
At each step, find the leftmost 0 digit of your value. Set it, and clear all digits to the left of it. If you don't find a 0 digit, then you've overflowed: return 0, or stop, or crash, or whatever you want.
This is what happens on a normal binary increment (by which I mean it's the effect, not how it's implemented in hardware), but we're doing it on the left instead of the right.
Whether you do this in bit ops, strings, or whatever, is up to you. If you do it in bitops, then a clz (or call to an equivalent hibit-style function) on ~value might be the most efficient way: __builtin_clz where available. But that's an implementation detail.
This solution was originally in binary and converted to conventional math as the requester specified.
It would make more sense as binary, at least the multiply by 2 and divide by 2 should be << 1 and >> 1 for speed, the additions and subtractions probably don't matter one way or the other.
If you pass in mask instead of nBits, and use bitshifting instead of multiplying or dividing, and change the tail recursion to a loop, this will probably be the most performant solution you'll find since every other call it will be nothing but a single add, it would only be as slow as Alnitak's solution once every 4, maybe even 8 calls.
int incrementBizarre(int initial, int nBits)
// in the 3 bit example, this should create 100
mask=2^(nBits-1)
// This should only return true if the first (least significant) bit is not set
// if initial is 011 and mask is 100
// 3 4, bit is not set
if(initial < mask)
// If it was not, just set it and bail.
return initial+ mask // 011 (3) + 100 (4) = 111 (7)
else
// it was set, are we at the most significant bit yet?
// mask 100 (4) / 2 = 010 (2), 001/2 = 0 indicating overflow
if(mask / 2) > 0
// No, we were't, so unset it (initial-mask) and increment the next bit
return incrementBizarre(initial - mask, mask/2)
else
// Whoops we were at the most significant bit. Error condition
throw new OverflowedMyBitsException()
Wow, that turned out kinda cool. I didn't figure in the recursion until the last second there.
It feels wrong--like there are some operations that should not work, but they do because of the nature of what you are doing (like it feels like you should get into trouble when you are operating on a bit and some bits to the left are non-zero, but it turns out you can't ever be operating on a bit unless all the bits to the left are zero--which is a very strange condition, but true.
Example of flow to get from 110 to 001 (backwards 3 to backwards 4):
mask 100 (4), initial 110 (6); initial < mask=false; initial-mask = 010 (2), now try on the next bit
mask 010 (2), initial 010 (2); initial < mask=false; initial-mask = 000 (0), now inc the next bit
mask 001 (1), initial 000 (0); initial < mask=true; initial + mask = 001--correct answer
Here's a solution from my answer to a different question that computes the next bit-reversed index without looping. It relies heavily on bit operations, though.
The key idea is that incrementing a number simply flips a sequence of least-significant bits, for example from nnnn0111 to nnnn1000. So in order to compute the next bit-reversed index, you have to flip a sequence of most-significant bits. If your target platform has a CTZ ("count trailing zeros") instruction, this can be done efficiently.
Example in C using GCC's __builtin_ctz:
void iter_reversed(unsigned bits) {
unsigned n = 1 << bits;
for (unsigned i = 0, j = 0; i < n; i++) {
printf("%x\n", j);
// Compute a mask of LSBs.
unsigned mask = i ^ (i + 1);
// Length of the mask.
unsigned len = __builtin_ctz(~mask);
// Align the mask to MSB of n.
mask <<= bits - len;
// XOR with mask.
j ^= mask;
}
}
Without a CTZ instruction, you can also use integer division:
void iter_reversed(unsigned bits) {
unsigned n = 1 << bits;
for (unsigned i = 0, j = 0; i < n; i++) {
printf("%x\n", j);
// Find least significant zero bit.
unsigned bit = ~i & (i + 1);
// Using division to bit-reverse a single bit.
unsigned rev = (n / 2) / bit;
// XOR with mask.
j ^= (n - 1) & ~(rev - 1);
}
}
void reverse(int nMaxVal, int nBits)
{
int thisVal, bit, out;
// Calculate for each value from 0 to nMaxVal.
for (thisVal=0; thisVal<=nMaxVal; ++thisVal)
{
out = 0;
// Shift each bit from thisVal into out, in reverse order.
for (bit=0; bit<nBits; ++bit)
out = (out<<1) + ((thisVal>>bit) & 1)
}
printf("%d -> %d\n", thisVal, out);
}
Maybe increment from 0 to N (the "usual" way") and do ReverseBitOrder() for each iteration. You can find several implementations here (I like the LUT one the best).
Should be really quick.
Here's an answer in Perl. You don't say what comes after the all ones pattern, so I just return zero. I took out the bitwise operations so that it should be easy to translate into another language.
sub reverse_increment {
my($n, $bits) = #_;
my $carry = 2**$bits;
while($carry > 1) {
$carry /= 2;
if($carry > $n) {
return $carry + $n;
} else {
$n -= $carry;
}
}
return 0;
}
Here's a solution which doesn't actually try to do any addition, but exploits the on/off pattern of the seqence (most sig bit alternates every time, next most sig bit alternates every other time, etc), adjust n as desired:
#define FLIP(x, i) do { (x) ^= (1 << (i)); } while(0)
int main() {
int n = 3;
int max = (1 << n);
int x = 0;
for(int i = 1; i <= max; ++i) {
std::cout << x << std::endl;
/* if n == 3, this next part is functionally equivalent to this:
*
* if((i % 1) == 0) FLIP(x, n - 1);
* if((i % 2) == 0) FLIP(x, n - 2);
* if((i % 4) == 0) FLIP(x, n - 3);
*/
for(int j = 0; j < n; ++j) {
if((i % (1 << j)) == 0) FLIP(x, n - (j + 1));
}
}
}
How about adding 1 to the most significant bit, then carrying to the next (less significant) bit, if necessary. You could speed this up by operating on bytes:
Precompute a lookup table for counting in bit-reverse from 0 to 256 (00000000 -> 10000000, 10000000 -> 01000000, ..., 11111111 -> 00000000).
Set all bytes in your multi-byte number to zero.
Increment the most significant byte using the lookup table. If the byte is 0, increment the next byte using the lookup table. If the byte is 0, increment the next byte...
Go to step 3.
With n as your power of 2 and x the variable you want to step:
(defun inv-step (x n) ; the following is a function declaration
"returns a bit-inverse step of x, bounded by 2^n" ; documentation
(do ((i (expt 2 (- n 1)) ; loop, init of i
(/ i 2)) ; stepping of i
(s x)) ; init of s as x
((not (integerp i)) ; breaking condition
s) ; returned value if all bits are 1 (is 0 then)
(if (< s i) ; the loop's body: if s < i
(return-from inv-step (+ s i)) ; -> add i to s and return the result
(decf s i)))) ; else: reduce s by i
I commented it thoroughly as you may not be familiar with this syntax.
edit: here is the tail recursive version. It seems to be a little faster, provided that you have a compiler with tail call optimization.
(defun inv-step (x n)
(let ((i (expt 2 (- n 1))))
(cond ((= n 1)
(if (zerop x) 1 0)) ; this is really (logxor x 1)
((< x i)
(+ x i))
(t
(inv-step (- x i) (- n 1))))))
When you reverse 0 to 2^n-1 but their bit pattern reversed, you pretty much cover the entire 0-2^n-1 sequence
Sum = 2^n * (2^n+1)/2
O(1) operation. No need to do bit reversals
Edit: Of course original poster's question was about to do increment by (reversed) one, which makes things more simple than adding two random values. So nwellnhof's answer contains the algorithm already.
Summing two bit-reversal values
Here is one solution in php:
function RevSum ($a,$b) {
// loop until our adder, $b, is zero
while ($b) {
// get carry (aka overflow) bit for every bit-location by AND-operation
// 0 + 0 --> 00 no overflow, carry is "0"
// 0 + 1 --> 01 no overflow, carry is "0"
// 1 + 0 --> 01 no overflow, carry is "0"
// 1 + 1 --> 10 overflow! carry is "1"
$c = $a & $b;
// do 1-bit addition for every bit location at once by XOR-operation
// 0 + 0 --> 00 result = 0
// 0 + 1 --> 01 result = 1
// 1 + 0 --> 01 result = 1
// 1 + 1 --> 10 result = 0 (ignored that "1", already taken care above)
$a ^= $b;
// now: shift carry bits to the next bit-locations to be added to $a in
// next iteration.
// PHP_INT_MAX here is used to ensure that the most-significant bit of the
// $b will be cleared after shifting. see link in the side note below.
$b = ($c >> 1) & PHP_INT_MAX;
}
return $a;
}
Side note: See this question about shifting negative values.
And as for test; start from zero and increment value by 8-bit reversed one (10000000):
$value = 0;
$add = 0x80; // 10000000 <-- "one" as bit reversed
for ($count = 20; $count--;) { // loop 20 times
printf("%08b\n", $value); // show value as 8-bit binary
$value = RevSum($value, $add); // do addition
}
... will output:
00000000
10000000
01000000
11000000
00100000
10100000
01100000
11100000
00010000
10010000
01010000
11010000
00110000
10110000
01110000
11110000
00001000
10001000
01001000
11001000
Let assume number 1110101 and our task is to find next one.
1) Find zero on highest position and mark position as index.
11101010 (4th position, so index = 4)
2) Set to zero all bits on position higher than index.
00001010
3) Change founded zero from step 1) to '1'
00011010
That's it. This is by far the fastest algorithm since most of cpu's has instructions to achieve this very efficiently. Here is a C++ implementation which increment 64bit number in reversed patern.
#include <intrin.h>
unsigned __int64 reversed_increment(unsigned __int64 number)
{
unsigned long index, result;
_BitScanReverse64(&index, ~number); // returns index of the highest '1' on bit-reverse number (trick to find the highest '0')
result = _bzhi_u64(number, index); // set to '0' all bits at number higher than index position
result |= (unsigned __int64) 1 << index; // changes to '1' bit on index position
return result;
}
Its not hit your requirements to have "no bits" operations, however i fear there is now way how to achieve something similar without them.

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