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gofmt -w -r 'strings.Bytes(a) -> []byte(a)' src/cmd src/pkg test/bench gofmt -w -r 'strings.Runes(a) -> []int(a)' src/cmd src/pkg test/bench delete unused imports R=r CC=golang-dev https://golang.org/cl/224062
666 lines
18 KiB
Go
666 lines
18 KiB
Go
/*
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Redistribution and use in source and binary forms, with or without
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modification, are permitted provided that the following conditions are met:
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* Redistributions of source code must retain the above copyright
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notice, this list of conditions and the following disclaimer.
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* Redistributions in binary form must reproduce the above copyright
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notice, this list of conditions and the following disclaimer in the
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documentation and/or other materials provided with the distribution.
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* Neither the name of "The Computer Language Benchmarks Game" nor the
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name of "The Computer Language Shootout Benchmarks" nor the names of
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its contributors may be used to endorse or promote products derived
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from this software without specific prior written permission.
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THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS"
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AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
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IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
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ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE
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LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
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CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
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SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
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INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
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CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
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ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
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POSSIBILITY OF SUCH DAMAGE.
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*/
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/* The Computer Language Benchmarks Game
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* http://shootout.alioth.debian.org/
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*
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* contributed by The Go Authors.
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* based on meteor-contest.c by Christian Vosteen
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*/
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package main
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import (
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"flag"
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"fmt"
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)
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var max_solutions = flag.Int("n", 2100, "maximum number of solutions")
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func boolInt(b bool) int8 {
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if b {
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return 1
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}
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return 0
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}
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/* The board is a 50 cell hexagonal pattern. For . . . . .
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* maximum speed the board will be implemented as . . . . .
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* 50 bits, which will fit into a 64 bit long long . . . . .
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* int. . . . . .
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* . . . . .
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* I will represent 0's as empty cells and 1's . . . . .
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* as full cells. . . . . .
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* . . . . .
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* . . . . .
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* . . . . .
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*/
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var board uint64 = 0xFFFC000000000000
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/* The puzzle pieces must be specified by the path followed
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* from one end to the other along 12 hexagonal directions.
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*
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* Piece 0 Piece 1 Piece 2 Piece 3 Piece 4
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*
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* O O O O O O O O O O O O O O O
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* O O O O O O O
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* O O O
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*
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* Piece 5 Piece 6 Piece 7 Piece 8 Piece 9
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*
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* O O O O O O O O O O O O O
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* O O O O O O O O O
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* O O O
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*
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* I had to make it 12 directions because I wanted all of the
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* piece definitions to fit into the same size arrays. It is
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* not possible to define piece 4 in terms of the 6 cardinal
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* directions in 4 moves.
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*/
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const (
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E = iota
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ESE
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SE
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S
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SW
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WSW
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W
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WNW
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NW
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N
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NE
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ENE
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PIVOT
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)
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var piece_def = [10][4]int8{
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[4]int8{E, E, E, SE},
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[4]int8{SE, E, NE, E},
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[4]int8{E, E, SE, SW},
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[4]int8{E, E, SW, SE},
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[4]int8{SE, E, NE, S},
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[4]int8{E, E, SW, E},
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[4]int8{E, SE, SE, NE},
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[4]int8{E, SE, SE, W},
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[4]int8{E, SE, E, E},
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[4]int8{E, E, E, SW},
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}
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/* To minimize the amount of work done in the recursive solve function below,
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* I'm going to allocate enough space for all legal rotations of each piece
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* at each position on the board. That's 10 pieces x 50 board positions x
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* 12 rotations. However, not all 12 rotations will fit on every cell, so
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* I'll have to keep count of the actual number that do.
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* The pieces are going to be unsigned long long ints just like the board so
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* they can be bitwise-anded with the board to determine if they fit.
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* I'm also going to record the next possible open cell for each piece and
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* location to reduce the burden on the solve function.
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*/
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var (
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pieces [10][50][12]uint64
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piece_counts [10][50]int
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next_cell [10][50][12]int8
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)
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/* Returns the direction rotated 60 degrees clockwise */
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func rotate(dir int8) int8 { return (dir + 2) % PIVOT }
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/* Returns the direction flipped on the horizontal axis */
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func flip(dir int8) int8 { return (PIVOT - dir) % PIVOT }
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/* Returns the new cell index from the specified cell in the
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* specified direction. The index is only valid if the
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* starting cell and direction have been checked by the
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* out_of_bounds function first.
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*/
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func shift(cell, dir int8) int8 {
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switch dir {
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case E:
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return cell + 1
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case ESE:
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if ((cell / 5) % 2) != 0 {
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return cell + 7
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} else {
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return cell + 6
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}
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case SE:
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if ((cell / 5) % 2) != 0 {
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return cell + 6
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} else {
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return cell + 5
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}
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case S:
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return cell + 10
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case SW:
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if ((cell / 5) % 2) != 0 {
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return cell + 5
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} else {
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return cell + 4
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}
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case WSW:
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if ((cell / 5) % 2) != 0 {
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return cell + 4
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} else {
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return cell + 3
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}
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case W:
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return cell - 1
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case WNW:
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if ((cell / 5) % 2) != 0 {
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return cell - 6
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} else {
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return cell - 7
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}
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case NW:
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if ((cell / 5) % 2) != 0 {
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return cell - 5
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} else {
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return cell - 6
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}
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case N:
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return cell - 10
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case NE:
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if ((cell / 5) % 2) != 0 {
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return cell - 4
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} else {
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return cell - 5
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}
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case ENE:
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if ((cell / 5) % 2) != 0 {
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return cell - 3
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} else {
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return cell - 4
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}
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}
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return cell
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}
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/* Returns wether the specified cell and direction will land outside
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* of the board. Used to determine if a piece is at a legal board
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* location or not.
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*/
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func out_of_bounds(cell, dir int8) bool {
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switch dir {
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case E:
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return cell%5 == 4
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case ESE:
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i := cell % 10
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return i == 4 || i == 8 || i == 9 || cell >= 45
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case SE:
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return cell%10 == 9 || cell >= 45
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case S:
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return cell >= 40
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case SW:
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return cell%10 == 0 || cell >= 45
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case WSW:
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i := cell % 10
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return i == 0 || i == 1 || i == 5 || cell >= 45
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case W:
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return cell%5 == 0
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case WNW:
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i := cell % 10
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return i == 0 || i == 1 || i == 5 || cell < 5
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case NW:
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return cell%10 == 0 || cell < 5
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case N:
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return cell < 10
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case NE:
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return cell%10 == 9 || cell < 5
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case ENE:
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i := cell % 10
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return i == 4 || i == 8 || i == 9 || cell < 5
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}
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return false
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}
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/* Rotate a piece 60 degrees clockwise */
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func rotate_piece(piece int) {
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for i := 0; i < 4; i++ {
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piece_def[piece][i] = rotate(piece_def[piece][i])
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}
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}
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/* Flip a piece along the horizontal axis */
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func flip_piece(piece int) {
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for i := 0; i < 4; i++ {
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piece_def[piece][i] = flip(piece_def[piece][i])
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}
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}
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/* Convenience function to quickly calculate all of the indices for a piece */
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func calc_cell_indices(cell []int8, piece int, index int8) {
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cell[0] = index
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for i := 1; i < 5; i++ {
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cell[i] = shift(cell[i-1], piece_def[piece][i-1])
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}
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}
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/* Convenience function to quickly calculate if a piece fits on the board */
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func cells_fit_on_board(cell []int8, piece int) bool {
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return !out_of_bounds(cell[0], piece_def[piece][0]) &&
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!out_of_bounds(cell[1], piece_def[piece][1]) &&
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!out_of_bounds(cell[2], piece_def[piece][2]) &&
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!out_of_bounds(cell[3], piece_def[piece][3])
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}
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/* Returns the lowest index of the cells of a piece.
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* I use the lowest index that a piece occupies as the index for looking up
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* the piece in the solve function.
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*/
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func minimum_of_cells(cell []int8) int8 {
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minimum := cell[0]
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for i := 1; i < 5; i++ {
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if cell[i] < minimum {
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minimum = cell[i]
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}
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}
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return minimum
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}
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/* Calculate the lowest possible open cell if the piece is placed on the board.
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* Used to later reduce the amount of time searching for open cells in the
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* solve function.
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*/
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func first_empty_cell(cell []int8, minimum int8) int8 {
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first_empty := minimum
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for first_empty == cell[0] || first_empty == cell[1] ||
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first_empty == cell[2] || first_empty == cell[3] ||
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first_empty == cell[4] {
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first_empty++
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}
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return first_empty
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}
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/* Generate the unsigned long long int that will later be anded with the
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* board to determine if it fits.
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*/
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func bitmask_from_cells(cell []int8) uint64 {
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var piece_mask uint64
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for i := 0; i < 5; i++ {
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piece_mask |= 1 << uint(cell[i])
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}
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return piece_mask
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}
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/* Record the piece and other important information in arrays that will
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* later be used by the solve function.
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*/
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func record_piece(piece int, minimum int8, first_empty int8, piece_mask uint64) {
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pieces[piece][minimum][piece_counts[piece][minimum]] = piece_mask
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next_cell[piece][minimum][piece_counts[piece][minimum]] = first_empty
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piece_counts[piece][minimum]++
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}
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/* Fill the entire board going cell by cell. If any cells are "trapped"
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* they will be left alone.
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*/
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func fill_contiguous_space(board []int8, index int8) {
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if board[index] == 1 {
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return
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}
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board[index] = 1
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if !out_of_bounds(index, E) {
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fill_contiguous_space(board, shift(index, E))
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}
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if !out_of_bounds(index, SE) {
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fill_contiguous_space(board, shift(index, SE))
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}
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if !out_of_bounds(index, SW) {
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fill_contiguous_space(board, shift(index, SW))
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}
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if !out_of_bounds(index, W) {
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fill_contiguous_space(board, shift(index, W))
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}
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if !out_of_bounds(index, NW) {
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fill_contiguous_space(board, shift(index, NW))
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}
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if !out_of_bounds(index, NE) {
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fill_contiguous_space(board, shift(index, NE))
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}
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}
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/* To thin the number of pieces, I calculate if any of them trap any empty
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* cells at the edges. There are only a handful of exceptions where the
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* the board can be solved with the trapped cells. For example: piece 8 can
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* trap 5 cells in the corner, but piece 3 can fit in those cells, or piece 0
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* can split the board in half where both halves are viable.
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*/
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func has_island(cell []int8, piece int) bool {
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temp_board := make([]int8, 50)
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var i int
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for i = 0; i < 5; i++ {
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temp_board[cell[i]] = 1
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}
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i = 49
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for temp_board[i] == 1 {
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i--
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}
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fill_contiguous_space(temp_board, int8(i))
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c := 0
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for i = 0; i < 50; i++ {
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if temp_board[i] == 0 {
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c++
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}
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}
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if c == 0 || (c == 5 && piece == 8) || (c == 40 && piece == 8) ||
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(c%5 == 0 && piece == 0) {
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return false
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}
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return true
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}
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/* Calculate all six rotations of the specified piece at the specified index.
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* We calculate only half of piece 3's rotations. This is because any solution
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* found has an identical solution rotated 180 degrees. Thus we can reduce the
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* number of attempted pieces in the solve algorithm by not including the 180-
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* degree-rotated pieces of ONE of the pieces. I chose piece 3 because it gave
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* me the best time ;)
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*/
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func calc_six_rotations(piece, index int) {
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cell := make([]int8, 5)
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for rotation := 0; rotation < 6; rotation++ {
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if piece != 3 || rotation < 3 {
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calc_cell_indices(cell, piece, int8(index))
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if cells_fit_on_board(cell, piece) && !has_island(cell, piece) {
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minimum := minimum_of_cells(cell)
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first_empty := first_empty_cell(cell, minimum)
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piece_mask := bitmask_from_cells(cell)
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record_piece(piece, minimum, first_empty, piece_mask)
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}
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}
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rotate_piece(piece)
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}
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}
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/* Calculate every legal rotation for each piece at each board location. */
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func calc_pieces() {
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for piece := 0; piece < 10; piece++ {
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for index := 0; index < 50; index++ {
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calc_six_rotations(piece, index)
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flip_piece(piece)
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calc_six_rotations(piece, index)
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}
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}
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}
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/* Calculate all 32 possible states for a 5-bit row and all rows that will
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* create islands that follow any of the 32 possible rows. These pre-
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* calculated 5-bit rows will be used to find islands in a partially solved
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* board in the solve function.
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*/
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const (
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ROW_MASK = 0x1F
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TRIPLE_MASK = 0x7FFF
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)
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var (
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all_rows = [32]int8{0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16,
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17, 18, 19, 20, 21, 22, 23, 24, 25, 26, 27, 28, 29, 30, 31,
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}
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bad_even_rows [32][32]int8
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bad_odd_rows [32][32]int8
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bad_even_triple [32768]int8
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bad_odd_triple [32768]int8
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)
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func rows_bad(row1, row2 int8, even bool) int8 {
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/* even is referring to row1 */
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var row2_shift int8
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/* Test for blockages at same index and shifted index */
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if even {
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row2_shift = ((row2 << 1) & ROW_MASK) | 0x01
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} else {
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row2_shift = (row2 >> 1) | 0x10
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}
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block := ((row1 ^ row2) & row2) & ((row1 ^ row2_shift) & row2_shift)
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/* Test for groups of 0's */
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in_zeroes := false
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group_okay := false
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for i := uint8(0); i < 5; i++ {
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if row1&(1<<i) != 0 {
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if in_zeroes {
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if !group_okay {
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return 1
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}
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in_zeroes = false
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group_okay = false
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}
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} else {
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if !in_zeroes {
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in_zeroes = true
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}
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if (block & (1 << i)) == 0 {
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group_okay = true
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}
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}
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}
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if in_zeroes {
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return boolInt(!group_okay)
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}
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return 0
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}
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/* Check for cases where three rows checked sequentially cause a false
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* positive. One scenario is when 5 cells may be surrounded where piece 5
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* or 7 can fit. The other scenario is when piece 2 creates a hook shape.
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*/
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func triple_is_okay(row1, row2, row3 int, even bool) bool {
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if even {
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/* There are four cases:
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* row1: 00011 00001 11001 10101
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* row2: 01011 00101 10001 10001
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* row3: 011?? 00110 ????? ?????
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*/
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return ((row1 == 0x03) && (row2 == 0x0B) && ((row3 & 0x1C) == 0x0C)) ||
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((row1 == 0x01) && (row2 == 0x05) && (row3 == 0x06)) ||
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((row1 == 0x19) && (row2 == 0x11)) ||
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((row1 == 0x15) && (row2 == 0x11))
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}
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/* There are two cases:
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* row1: 10011 10101
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* row2: 10001 10001
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* row3: ????? ?????
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*/
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return ((row1 == 0x13) && (row2 == 0x11)) ||
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((row1 == 0x15) && (row2 == 0x11))
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}
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func calc_rows() {
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for row1 := int8(0); row1 < 32; row1++ {
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for row2 := int8(0); row2 < 32; row2++ {
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bad_even_rows[row1][row2] = rows_bad(row1, row2, true)
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bad_odd_rows[row1][row2] = rows_bad(row1, row2, false)
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}
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}
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for row1 := 0; row1 < 32; row1++ {
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for row2 := 0; row2 < 32; row2++ {
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for row3 := 0; row3 < 32; row3++ {
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result1 := bad_even_rows[row1][row2]
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result2 := bad_odd_rows[row2][row3]
|
|
if result1 == 0 && result2 != 0 && triple_is_okay(row1, row2, row3, true) {
|
|
bad_even_triple[row1+(row2*32)+(row3*1024)] = 0
|
|
} else {
|
|
bad_even_triple[row1+(row2*32)+(row3*1024)] = boolInt(result1 != 0 || result2 != 0)
|
|
}
|
|
|
|
result1 = bad_odd_rows[row1][row2]
|
|
result2 = bad_even_rows[row2][row3]
|
|
if result1 == 0 && result2 != 0 && triple_is_okay(row1, row2, row3, false) {
|
|
bad_odd_triple[row1+(row2*32)+(row3*1024)] = 0
|
|
} else {
|
|
bad_odd_triple[row1+(row2*32)+(row3*1024)] = boolInt(result1 != 0 || result2 != 0)
|
|
}
|
|
}
|
|
}
|
|
}
|
|
}
|
|
|
|
|
|
/* Calculate islands while solving the board.
|
|
*/
|
|
func boardHasIslands(cell int8) int8 {
|
|
/* Too low on board, don't bother checking */
|
|
if cell >= 40 {
|
|
return 0
|
|
}
|
|
current_triple := (board >> uint((cell/5)*5)) & TRIPLE_MASK
|
|
if (cell/5)%2 != 0 {
|
|
return bad_odd_triple[current_triple]
|
|
}
|
|
return bad_even_triple[current_triple]
|
|
}
|
|
|
|
|
|
/* The recursive solve algorithm. Try to place each permutation in the upper-
|
|
* leftmost empty cell. Mark off available pieces as it goes along.
|
|
* Because the board is a bit mask, the piece number and bit mask must be saved
|
|
* at each successful piece placement. This data is used to create a 50 char
|
|
* array if a solution is found.
|
|
*/
|
|
var (
|
|
avail uint16 = 0x03FF
|
|
sol_nums [10]int8
|
|
sol_masks [10]uint64
|
|
solutions [2100][50]int8
|
|
solution_count = 0
|
|
)
|
|
|
|
func record_solution() {
|
|
for sol_no := 0; sol_no < 10; sol_no++ {
|
|
sol_mask := sol_masks[sol_no]
|
|
for index := 0; index < 50; index++ {
|
|
if sol_mask&1 == 1 {
|
|
solutions[solution_count][index] = sol_nums[sol_no]
|
|
/* Board rotated 180 degrees is a solution too! */
|
|
solutions[solution_count+1][49-index] = sol_nums[sol_no]
|
|
}
|
|
sol_mask = sol_mask >> 1
|
|
}
|
|
}
|
|
solution_count += 2
|
|
}
|
|
|
|
func solve(depth, cell int8) {
|
|
if solution_count >= *max_solutions {
|
|
return
|
|
}
|
|
|
|
for board&(1<<uint(cell)) != 0 {
|
|
cell++
|
|
}
|
|
|
|
for piece := int8(0); piece < 10; piece++ {
|
|
var piece_no_mask uint16 = 1 << uint(piece)
|
|
if avail&piece_no_mask == 0 {
|
|
continue
|
|
}
|
|
avail ^= piece_no_mask
|
|
max_rots := piece_counts[piece][cell]
|
|
piece_mask := pieces[piece][cell]
|
|
for rotation := 0; rotation < max_rots; rotation++ {
|
|
if board&piece_mask[rotation] == 0 {
|
|
sol_nums[depth] = piece
|
|
sol_masks[depth] = piece_mask[rotation]
|
|
if depth == 9 {
|
|
/* Solution found!!!!!11!!ONE! */
|
|
record_solution()
|
|
avail ^= piece_no_mask
|
|
return
|
|
}
|
|
board |= piece_mask[rotation]
|
|
if boardHasIslands(next_cell[piece][cell][rotation]) == 0 {
|
|
solve(depth+1, next_cell[piece][cell][rotation])
|
|
}
|
|
board ^= piece_mask[rotation]
|
|
}
|
|
}
|
|
avail ^= piece_no_mask
|
|
}
|
|
}
|
|
|
|
/* pretty print a board in the specified hexagonal format */
|
|
func pretty(b *[50]int8) {
|
|
for i := 0; i < 50; i += 10 {
|
|
fmt.Printf("%c %c %c %c %c \n %c %c %c %c %c \n", b[i]+'0', b[i+1]+'0',
|
|
b[i+2]+'0', b[i+3]+'0', b[i+4]+'0', b[i+5]+'0', b[i+6]+'0',
|
|
b[i+7]+'0', b[i+8]+'0', b[i+9]+'0')
|
|
}
|
|
fmt.Printf("\n")
|
|
}
|
|
|
|
/* Find smallest and largest solutions */
|
|
func smallest_largest() (smallest, largest *[50]int8) {
|
|
smallest = &solutions[0]
|
|
largest = &solutions[0]
|
|
for i := 1; i < solution_count; i++ {
|
|
candidate := &solutions[i]
|
|
for j, s := range *smallest {
|
|
c := candidate[j]
|
|
if c == s {
|
|
continue
|
|
}
|
|
if c < s {
|
|
smallest = candidate
|
|
}
|
|
break
|
|
}
|
|
for j, s := range *largest {
|
|
c := candidate[j]
|
|
if c == s {
|
|
continue
|
|
}
|
|
if c > s {
|
|
largest = candidate
|
|
}
|
|
break
|
|
}
|
|
}
|
|
return
|
|
}
|
|
|
|
func main() {
|
|
flag.Parse()
|
|
calc_pieces()
|
|
calc_rows()
|
|
solve(0, 0)
|
|
fmt.Printf("%d solutions found\n\n", solution_count)
|
|
smallest, largest := smallest_largest()
|
|
pretty(smallest)
|
|
pretty(largest)
|
|
}
|