I am implementing several datastructures and one primitive I want to use is the following: I have a memory chunk A[N] (it has a variable length, but I take 100 for my examples) and inside this chunk, there is a smaller part C of length K (lets say 30) which I want to move without using any additional memory.

The additional difficulty is, that A "wraps", that is, C can start at A[80] and then the first 20 elements of C are the elements A[80..100] and the last 10 elements are the elements A[0..10]. Furthermore, the target range may also "wrap" and overlap with C in any possible way. Additionally, I don't want to use more than a constant amount of additional memory, everything should happen in place. Also, the part of A which is neither in the target range nor in the source range may contain something important, so it cannot be used either. So one case would be the following:

A looks like this:

|456789ABCDEF0123456789AB|-----|0123|

And should be transformed to this:

|89AB|-----|0123456789ABCDEF01234567|

Just delegating it to a library or use another datastructure from a library is not an option here, I want to understand the problem myself. On the first sight, I thought that it might not be trivial, but as soon as you distinguish a few cases, it becomes clear, but now I am having serious trouble. Of course there are the trivial cases if they don't overlap or don't wrap, but at least if both happens at the same time, it gets messy. You could start with one free place and move the part that belongs there, but then you create another free part somewhere else and it gets hard to keep track of which parts you can stil use.

Maybe I am missing something completely, but even my special case if the target range does not wrap has almost 100 lines (half of it are assertions and comments, though) and I could update it so that it also handles the general case with some additional index calculations, but if someone has an elegant and short solution, I would appreciate some help. Intuitively I think that this should somehow be trivial, but I just don't see the best solution yet.

Note: The interesting case is of course, if C is almost as big as A. If |C| < N/2, it is trivial.

edit: Using more than a constant amount of additional flags/indices counts as additional memory and I want to avoid that if possible.

edit: Some people wanted to see my code. My question is rather abstract, so I didn't want to post it, but maybe someone sees how to improve it. It is terrible, it only works for the case that the target starts at the beginning (however, that can easily be changed) and terribly long, but it does the job without additional memory in O(n).

```
#include <stddef.h>
#include <stdio.h>
#include <string.h>
#include <assert.h>
void move_part(int* A, size_t N, size_t target, size_t source, size_t size, int show_steps)
{
assert(source + size <= N);
assert(target + size <= N);
if (show_steps) {
printf("Moving size %d from %d to %d.\n", size, source, target);
}
memmove(A + target, A + source, size * sizeof(int));
}
void swap_parts(int* A, size_t N, size_t first_begin, size_t second_begin, size_t size, int show_steps)
{
if (show_steps) {
printf("Swapping size %d at %d and %d.\n", size, first_begin, second_begin);
}
assert(first_begin + size <= N);
assert(second_begin + size <= N);
size_t i;
for (i = 0; i < size; ++i) {
int x = A[first_begin + i];
A[first_begin + i] = A[second_begin + i];
A[second_begin + i] = x;
}
}
void move_to_beginning(int* A, size_t N, size_t begin, size_t size, int show_steps)
{
assert(begin <= N);
assert(size <= N);
// Denotes the start of our "working range". Increases during
// the algorithm and becomes N
size_t part_start = 0;
// Note: Keeping the size is crucial since begin == end could
// mean that the range is empty or full.
size_t end = (begin + size) % N;
while (part_start != N) {
size_t i;
if (show_steps) {
for (i = 0; i < N; ++i) {
printf("%d ", A[i]);
}
printf("\n");
printf("part_start %d begin %d end %d size %d\n", part_start, begin, end, size);
}
// loop invariants
assert(part_start < N);
// The two pointers are in our range
assert(part_start <= begin && begin <= N);
assert(part_start <= end && end <= N);
// size is valid (wrapped case, non-empty, non-full case)
assert(begin <= end || (N - begin) + (end - part_start) == size);
// size is valid (non wrapped case, non-empty, non-full case)
assert(begin >= end || end - begin == size);
// size is valid (working range is full or empty case)
assert(begin != end || size == 0 || part_start + size == N);
if (size == 0 || begin == N || begin == part_start) {
// ##|1234|# -> 1234### ||
if (show_steps) {
printf("Case 1:\nTerminating\n");
}
// #||# -> ## ||
// 12|##| -> 12## ||
// |12|## -> 12## ||
break;
/* Not necessary any more, but would be the correct transformation:
part_start = N;
begin = N;
end = N;
size = 0;*/
} else if (end == part_start) {
// |##|123 -> ##|123|
if (show_steps) {
printf("Case 2:\n");
printf("Setting end to %d.\n", N);
}
end = N;
} else if (begin < end) {
// ##|1234|# -> 1234### ||
if (show_steps) {
printf("Case 3:\n");
}
move_part(A, N, part_start, begin, size, show_steps);
break;
/* Not necessary any more, but would be the correct transformation:
part_start = N;
begin = N;
end = N;
size = 0;*/
} else {
size_t end_size = end - part_start;
size_t begin_size = N - begin;
assert(begin_size + end_size == size);
if (end_size >= begin_size) {
// 345|#|12 -> 12 5|#|34
if (show_steps) {
printf("Case 4:\n");
}
swap_parts(A, N, part_start, begin, begin_size, show_steps);
assert(begin_size > 0); // Necessary for progress
part_start += begin_size;
size = end_size;
// begin, end remain unchanged
} else if (begin - part_start <= begin_size) {
// 56|#|1234 -> 123 56|#|4
size_t size_moved = begin - part_start;
assert(size_moved >= end_size); // else the next step would be more efficient
if (show_steps) {
printf("Case 5\n");
}
swap_parts(A, N, part_start, begin, end_size, show_steps);
move_part(A, N, end, begin + end_size, begin - end, show_steps);
assert(end_size + (begin - end) == size_moved);
size -= size_moved;
part_start = begin;
begin += size_moved;
end += size_moved;
} else if (end_size <= begin_size) {
// 45|##|123 -> 123 #|45|#
if (show_steps) {
printf("Case 6\n");
}
swap_parts(A, N, part_start, begin, end_size, show_steps);
move_part(A, N, end, begin + end_size, begin_size - end_size, show_steps);
part_start += begin_size;
size = end_size;
end = begin + end_size;
// begin remains unchanged
} else {
// No case applies, this should never happen
assert(0);
}
}
}
}
int main()
{
int N = 20;
int A[20];
size_t size = 17;
size_t begin = 15;
size_t i;
for (i = 0; i < size; ++i) {
A[(begin + i) % N] = i;
}
move_to_beginning(A, N, begin, size, 0);
for (i = 0; i < size; ++i) {
printf("%d ", A[i]);
}
printf("\n");
return 0;
}
```

`memmove`

, i.e. copy where source and dest ranges may overlap? Or are you trying to do a completely non-destructive operation where the data that would be clobbered is simultaneously moved to "old" part of the source range? – R.. Sep 9 '12 at 15:53the part of A which is neither in the target range nor in the source range may contain something important" – gcbenison Sep 9 '12 at 16:15`XXXXXyyyZZZZZZZZZZ`

instead of your`CC---CCCC`

form, it would be possible for us to track where the individual elements need to go. – wildplasser Sep 9 '12 at 17:46