Difference between revisions of "Pre-calculated cycles for 8x3 matrix transpose"
From Just in Time
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<source lang="cpp"> | <source lang="cpp"> | ||
| + | #include <iostream> | ||
/** | /** | ||
| − | * calculate cycles along which values should be rotated in | + | * calculate cycles along which values should be rotated in an array to perform |
| + | * a 8x3 matrix transformation. See: | ||
* https://en.wikipedia.org/wiki/In-place_matrix_transposition#Non-square_matrices:_Following_the_cycles | * https://en.wikipedia.org/wiki/In-place_matrix_transposition#Non-square_matrices:_Following_the_cycles | ||
* | * | ||
| Line 32: | Line 34: | ||
}; | }; | ||
| + | // keep on looping until all elements are at | ||
| + | // their destination position | ||
while (true) | while (true) | ||
{ | { | ||
| − | // find the starting point of | + | // find the starting point of a cycle |
int seed = 0; | int seed = 0; | ||
for (;seed<24;++seed) | for (;seed<24;++seed) | ||
| Line 40: | Line 44: | ||
if (positions[seed] != seed) break; | if (positions[seed] != seed) break; | ||
} | } | ||
| − | if (seed == 24) break; // everything in | + | if (seed == 24) break; // everything in place |
| + | // seed is the first element of the cycle | ||
// now walk the cycle | // now walk the cycle | ||
std::cout << seed << ": "; | std::cout << seed << ": "; | ||
| Line 54: | Line 59: | ||
std::cout << '\n'; | std::cout << '\n'; | ||
} | } | ||
| + | } | ||
| + | |||
| + | int main() | ||
| + | { | ||
| + | findCycles(); | ||
} | } | ||
</source> | </source> | ||
| + | |||
| + | This [http://coliru.stacked-crooked.com/a/abaa4da1abfdae00 returns] the following: | ||
| + | |||
| + | <pre> | ||
| + | 1: 8 18 6 2 16 13 12 4 9 3 1 | ||
| + | 5: 17 21 7 10 11 19 14 20 22 15 5 | ||
| + | </pre> | ||
Latest revision as of 07:40, 30 September 2017
When driving 8 WS2811 strips in parallel with an 8Mhz AVR we need to transpose arrays of rgb-values into groups of red-, green- and blue values (rgbrgbrgb... to rrrrrrrrggggggggbbbbbbbb). This boils down to an in-place 8*3 matrix transpose. This again boils down to going through cycles like this:
- pick up the value at position 1
- place the saved value from the previous step at position 8, but first save the value at that location
- place the saved value from the previous step at position 18, but first save the value at that location
- place the saved value from the previous step at position 6, but first save the value at that location
- etc, etc...
Obviously, when doing this, you'd need a description of the cycles, i.e. which values need to be moved where. For 24 values, finding the cycles could be done with a set of numbered cards. But of course, in about the same time, you could whip up a program that does this. The program looks like this:
<source lang="cpp">
- include <iostream>
/**
* calculate cycles along which values should be rotated in an array to perform * a 8x3 matrix transformation. See: * https://en.wikipedia.org/wiki/In-place_matrix_transposition#Non-square_matrices:_Following_the_cycles * */
void findCycles() {
// this array describes for each cell in the array
// where its value should go to.
// e.g. positions[2] == 16 means that the value at
// position 2 needs to move to position 16
int positions[] = {
0, 8, 16,
1, 9, 17,
2, 10, 18,
3, 11, 19,
4, 12, 20,
5, 13, 21,
6, 14, 22,
7, 15, 23
};
// keep on looping until all elements are at
// their destination position
while (true)
{
// find the starting point of a cycle
int seed = 0;
for (;seed<24;++seed)
{
if (positions[seed] != seed) break;
}
if (seed == 24) break; // everything in place
// seed is the first element of the cycle
// now walk the cycle
std::cout << seed << ": ";
int transfer = positions[seed];
positions[seed] = -1;
while (transfer != -1)
{
std::cout << transfer << " ";
std::swap( positions[transfer], transfer);
}
std::cout << '\n';
}
}
int main() {
findCycles();
} </source>
This returns the following:
1: 8 18 6 2 16 13 12 4 9 3 1 5: 17 21 7 10 11 19 14 20 22 15 5