/*************************************************************************** * __________ __ ___. * Open \______ \ ____ ____ | | _\_ |__ _______ ___ * Source | _// _ \_/ ___\| |/ /| __ \ / _ \ \/ / * Jukebox | | ( <_> ) \___| < | \_\ ( <_> > < < * Firmware |____|_ /\____/ \___ >__|_ \|___ /\____/__/\_ \ * \/ \/ \/ \/ \/ * $Id$ * * Copyright (C) 2005 Dave Chapman * * All files in this archive are subject to the GNU General Public License. * See the file COPYING in the source tree root for full license agreement. * * This software is distributed on an "AS IS" basis, WITHOUT WARRANTY OF ANY * KIND, either express or implied. * ****************************************************************************/ /*** Sudoku by Dave Chapman User instructions ----------------- Use the arrow keys to move cursor, and press SELECT/ON/F2 to increment the number under the cursor. At any time during the game, press On to bring up the game menu with further options: Save Reload Clear Solve Sudoku is implemented as a "viewer" for a ".ss" file, as generated by Simple Sudoku and other applications - http://angusj.com/sudoku/ In-progress game positions are saved in the original .ss file, with A-I used to indicate numbers entered by the user. Example ".ss" file, and one with a saved state: ...|...|... ...|...|... 2..|8.4|9.1 2.C|8.4|9.1 ...|1.6|32. E..|1.6|32. ----------- ----------- ...|..5|.4. ...|..5|.4. 8..|423|..6 8..|423|..6 .3.|9..|... .3D|9..|A.. ----------- ----------- .63|7.9|... .63|7.9|... 4.9|5.2|..8 4.9|5.2|.C8 ...|...|... ...|...|... */ #include "plugin.h" #ifdef HAVE_LCD_BITMAP #include #include "sudoku.h" #include "generator.h" PLUGIN_HEADER /* here is a global api struct pointer. while not strictly necessary, it's nice not to have to pass the api pointer in all function calls in the plugin */ struct plugin_api* rb; /* The bitmaps */ extern const fb_data sudoku_normal[]; extern const fb_data sudoku_start[]; extern const fb_data sudoku_inverse[]; #if (LCD_HEIGHT==128) && (LCD_WIDTH==160) /* For iriver H1x0 - 160x128, 9 cells @ 12x12 with 14 border lines*/ /* Internal dimensions of a cell */ #define CELL_WIDTH 12 #define CELL_HEIGHT 12 #define BOARD_WIDTH (CELL_WIDTH*9+10+4) #define BOARD_HEIGHT (CELL_HEIGHT*9+10+4) #define XOFS (((LCD_WIDTH-BOARD_WIDTH)/2)+10) #define YOFS ((LCD_HEIGHT-BOARD_HEIGHT)/2) #define XOFSSCRATCHPAD 3 /* Locations of each cell */ static unsigned char cellxpos[9]={ 2, 15, 28, 42, 55, 68, 82, 95, 108 }; static unsigned char cellypos[9]={ 2, 15, 28, 42, 55, 68, 82, 95, 108 }; /* The height of one cell in the bitmap */ #define BITMAP_HEIGHT 12 #define BITMAP_STRIDE 12 #elif (LCD_HEIGHT==64) && (LCD_WIDTH==112) /* For Archos Recorder, FM and Ondio (112x64): 9 cells @ 8x6 with 10 border lines */ /* Internal dimensions of a cell */ #define CELL_WIDTH 8 #define CELL_HEIGHT 6 #define BOARD_WIDTH (CELL_WIDTH*9+10) #define BOARD_HEIGHT (CELL_HEIGHT*9+10) #define XOFS (((LCD_WIDTH-BOARD_WIDTH)/2)+7) #define YOFS ((LCD_HEIGHT-BOARD_HEIGHT)/2) #define XOFSSCRATCHPAD 2 /* Locations of each cell */ static unsigned char cellxpos[9]={ 1, 10, 19, 28, 37, 46, 55, 64, 73 }; static unsigned char cellypos[9]={ 1, 8, 15, 22, 29, 36, 43, 50, 57 }; /* The height of one cell in the bitmap */ #define BITMAP_HEIGHT 8 #define BITMAP_STRIDE 8 #elif (LCD_HEIGHT>=176) && (LCD_WIDTH>=220) /* iriver h300 */ /* Internal dimensions of a cell */ #define CELL_WIDTH 16 #define CELL_HEIGHT 16 #define BOARD_WIDTH (CELL_WIDTH*9+10+4) #define BOARD_HEIGHT (CELL_HEIGHT*9+10+4) #define XOFS (((LCD_WIDTH-BOARD_WIDTH)/2)+15) #define YOFS ((LCD_HEIGHT-BOARD_HEIGHT)/2) #define XOFSSCRATCHPAD 10 /* Locations of each cell */ static unsigned char cellxpos[9]={ 2, 19, 36, 54, 71, 88, 106, 123, 140 }; static unsigned char cellypos[9]={ 2, 19, 36, 54, 71, 88, 106, 123, 140 }; /* The height of one cell in the bitmap */ #define BITMAP_HEIGHT 16 #define BITMAP_STRIDE 16 #else #error SUDOKU: Unsupported LCD size #endif /****** Solver routine by Tom Shackell Downloaded from: http://www-users.cs.york.ac.uk/~shackell/sudoku/Sudoku.html Released under GPLv2 */ typedef unsigned int Bitset; #define BLOCK 3 #define SIZE (BLOCK*BLOCK) #define true 1 #define false 0 typedef struct _Sudoku { Bitset table[SIZE][SIZE]; }Sudoku; typedef struct _Stats { int numTries; int backTracks; int numEmpty; bool solutionFound; }Stats; typedef struct _Options { bool allSolutions; bool uniquenessCheck; }Options; void sudoku_init(Sudoku* sud); void sudoku_set(Sudoku* sud, int x, int y, int num, bool original); int sudoku_get(Sudoku* sud, int x, int y, bool* original); #define BIT(n) ((Bitset)(1<<(n))) #define BIT_TEST(v,n) ((((Bitset)v) & BIT(n)) != 0) #define BIT_CLEAR(v,n) (v) &= ~BIT(n) #define MARK_BIT BIT(0) #define ORIGINAL_BIT BIT(SIZE+1) #define ALL_BITS (BIT(1) | BIT(2) | BIT(3) | BIT(4) | BIT(5) | BIT(6) | BIT(7) | BIT(8) | BIT(9)) /* initialize a sudoku problem, should be called before using set or get */ void sudoku_init(Sudoku* sud) { int y, x; for (y = 0; y < SIZE; y++){ for (x = 0; x < SIZE; x++){ sud->table[x][y] = ALL_BITS; } } } /* set the number at a particular x and y column */ void sudoku_set(Sudoku* sud, int x, int y, int num, bool original) { int i, j; int bx, by; Bitset orig; /* clear the row and columns */ for (i = 0; i < SIZE; i++){ BIT_CLEAR(sud->table[i][y], num); BIT_CLEAR(sud->table[x][i], num); } /* clear the block */ bx = x - (x % BLOCK); by = y - (y % BLOCK); for (i = 0; i < BLOCK; i++){ for (j = 0; j < BLOCK; j++){ BIT_CLEAR(sud->table[bx+j][by+i], num); } } /* mark the table */ orig = original ? ORIGINAL_BIT : 0; sud->table[x][y] = BIT(num) | MARK_BIT | orig; } /* get the number at a particular x and y column, if this is not unique return 0 */ int sudoku_get(Sudoku* sud, int x, int y, bool* original) { Bitset val = sud->table[x][y]; int result = 0; int i; if (original) { *original = val & ORIGINAL_BIT; } for (i = 1; i <= SIZE; i++){ if (BIT_TEST(val, i)){ if (result != 0){ return 0; } result = i; } } return result; } /* returns true if this is a valid problem, this is necessary because the input problem might be degenerate which breaks the solver algorithm. */ static bool is_valid(const Sudoku* sud) { int x, y; for (y = 0; y < SIZE; y++){ for (x = 0; x < SIZE; x++){ if ((sud->table[x][y] & ALL_BITS) == 0){ return false; } } } return true; } /* scan the table for the most constrained item, giving all it's options, sets the best x and y coordinates, the number of options and the options for that coordinate and returns true if the puzzle is finished */ static bool scan(const Sudoku* sud, int* rX, int* rY, int *num, int* options) { int x, y, i, j; int bestCount = SIZE+1; Bitset val; bool allMarked = true; for (y = 0; y < SIZE; y++){ for (x = 0; x < SIZE; x++){ Bitset val = sud->table[x][y]; int i; int count = 0; if (val & MARK_BIT) { /* already set */ continue; } allMarked = false; for (i = 1; i <= SIZE; i++){ if (BIT_TEST(val, i)){ count++; } } if (count < bestCount){ bestCount = count; *rX = x; *rY = y; if (count == 0){ /* can't possibly be beaten */ *num = 0; return false; } } } } /* now copy into options */ *num = bestCount; val = sud->table[*rX][*rY]; for (i = 1, j = 0; i <= SIZE; i++){ if (BIT_TEST(val, i)){ options[j++] = i; } } return allMarked; } static bool solve(Sudoku* sud, Stats* stats, const Options* options); /* try a particular option and return true if that gives a solution or false if it doesn't, restores board on backtracking */ static bool spawn_option(Sudoku* sud, Stats* stats, const Options* options, int x, int y, int num) { Sudoku copy; rb->memcpy(©,sud,sizeof(Sudoku)); sudoku_set(©, x, y, num, false); stats->numTries += 1; if (solve(©, stats, options)){ if (!options->allSolutions && stats->solutionFound){ rb->memcpy(sud,©,sizeof(Sudoku)); } return true; }else{ stats->backTracks++; } return false; } /* solve a sudoku problem, returns true if there is a solution and false otherwise. stats is used to track statisticss */ static bool solve(Sudoku* sud, Stats* stats, const Options* options) { while (true){ int x, y, i, num; int places[SIZE]; if (scan(sud, &x, &y, &num, places)){ /* a solution was found! */ if (options->uniquenessCheck && stats->solutionFound){ /*printf("\n\t... But the solution is not unique!\n"); */ return true; } stats->solutionFound = true; if (options->allSolutions || options->uniquenessCheck){ /*printf("\n\tSolution after %d iterations\n", stats->numTries); */ /*sudoku_print(sud); */ return false; } else{ return true; } } if (num == 0){ /* can't be satisfied */ return false; } /* try all the places (except the last one) */ for (i = 0; i < num-1; i++){ if (spawn_option(sud, stats, options, x, y, places[i])){ /* solution found! */ if (!options->allSolutions && stats->solutionFound){ return true; } } } /* take the last place ourself */ stats->numTries += 1; sudoku_set(sud, x, y, places[num-1], false); } } /******** END OF IMPORTED CODE */ /* A wrapper function between the Sudoku plugin and the above solver code */ void sudoku_solve(struct sudoku_state_t* state) { bool ret; Stats stats; Options options; Sudoku sud; bool original; int r,c; /* Initialise the parameters */ sudoku_init(&sud); rb->memset(&stats,0,sizeof(stats)); options.allSolutions=false; options.uniquenessCheck=false; /* Convert Rockbox format into format for solver */ for (r=0;r<9;r++) { for (c=0;c<9;c++) { if (state->startboard[r][c]!='0') { sudoku_set(&sud, c, r, state->startboard[r][c]-'0', true); } } } /* need to check for degenerate input problems ... */ if (is_valid(&sud)){ ret = solve(&sud, &stats, &options); } else { ret = false; } if (ret) { /* Populate the board with the solution. */ for (r=0;r<9;r++) { for (c=0;c<9;c++) { state->currentboard[r][c]='0'+ sudoku_get(&sud, c, r, &original); } } } else { rb->splash(HZ*2, true, "Solve failed"); } return; } void clear_state(struct sudoku_state_t* state) { int r,c; state->filename[0]=0; for (r=0;r<9;r++) { for (c=0;c<9;c++) { state->startboard[r][c]='0'; state->currentboard[r][c]='0'; #ifdef SUDOKU_BUTTON_POSSIBLE state->possiblevals[r][c]=0; #endif } } state->x=0; state->y=0; state->editmode=0; } /* Load game - only ".ss" is officially supported, but any sensible text representation (one line per row) may load. */ bool load_sudoku(struct sudoku_state_t* state, char* filename) { int fd; size_t n; int r = 0, c = 0; unsigned int i; int valid=0; char buf[300]; /* A buffer to read a sudoku board from */ fd=rb->open(filename, O_RDONLY); if (fd < 0) { LOGF("Invalid sudoku file: %s\n",filename); return(false); } rb->strncpy(state->filename,filename,MAX_PATH); n=rb->read(fd,buf,300); if (n <= 0) { return(false); } rb->close(fd); r=0; c=0; i=0; while ((i < n) && (r < 9)) { switch (buf[i]){ case ' ': case '\t': if (c > 0) valid=1; break; case '|': case '*': case '-': case '\r': break; case '\n': if (valid) { r++; valid=0; } c = 0; break; case '_': case '.': valid=1; if (c >= SIZE || r >= SIZE){ LOGF("ERROR: sudoku problem is the wrong size (%d,%d)\n", c, r); return(false); } c++; break; default: if (((buf[i]>='A') && (buf[i]<='I')) || ((buf[i]>='0') && (buf[i]<='9'))) { valid=1; if (r >= SIZE || c >= SIZE){ LOGF("ERROR: sudoku problem is the wrong size " "(%d,%d)\n", c, r); return(false); } if ((buf[i]>='0') && (buf[i]<='9')) { state->startboard[r][c]=buf[i]; state->currentboard[r][c]=buf[i]; } else { state->currentboard[r][c]='1'+(buf[i]-'A'); } c++; } /* Ignore any other characters */ break; } i++; } /* Save a copy of the saved state - so we can reload without using the disk */ rb->memcpy(state->savedboard,state->currentboard,81); return(true); } bool save_sudoku(struct sudoku_state_t* state) { int fd; int r,c; int i; char line[13]; char sep[13]; rb->memcpy(line,"...|...|...\r\n",13); rb->memcpy(sep,"-----------\r\n",13); if (state->filename[0]==0) { return false; } fd=rb->open(state->filename, O_WRONLY|O_CREAT); if (fd >= 0) { for (r=0;r<9;r++) { i=0; for (c=0;c<9;c++) { if (state->startboard[r][c]!='0') { line[i]=state->startboard[r][c]; } else if (state->currentboard[r][c]!='0') { line[i]='A'+(state->currentboard[r][c]-'1'); } else { line[i]='.'; } i++; if ((c==2) || (c==5)) { i++; } } rb->write(fd,line,sizeof(line)); if ((r==2) || (r==5)) { rb->write(fd,sep,sizeof(sep)); } } /* Add a blank line at end */ rb->write(fd,"\r\n",2); rb->close(fd); /* Save a copy of the saved state - so we can reload without using the disk */ rb->memcpy(state->savedboard,state->currentboard,81); return true; } else { return false; } } void restore_state(struct sudoku_state_t* state) { rb->memcpy(state->currentboard,state->savedboard,81); } void clear_board(struct sudoku_state_t* state) { int r,c; for (r=0;r<9;r++) { for (c=0;c<9;c++) { state->currentboard[r][c]=state->startboard[r][c]; } } state->x=0; state->y=0; } void update_cell(struct sudoku_state_t* state, int r, int c) { /* We have four types of cell: 1) User-entered number 2) Starting number 3) Cursor in cell */ if ((r==state->y) && (c==state->x)) { rb->lcd_bitmap_part(sudoku_inverse,0, BITMAP_HEIGHT*(state->currentboard[r][c]-'0'), BITMAP_STRIDE, XOFS+cellxpos[c],YOFS+cellypos[r],CELL_WIDTH, CELL_HEIGHT); } else { if (state->startboard[r][c]!='0') { rb->lcd_bitmap_part(sudoku_start,0, BITMAP_HEIGHT*(state->startboard[r][c]-'0'), BITMAP_STRIDE, XOFS+cellxpos[c],YOFS+cellypos[r], CELL_WIDTH,CELL_HEIGHT); } else { rb->lcd_bitmap_part(sudoku_normal,0, BITMAP_HEIGHT*(state->currentboard[r][c]-'0'), BITMAP_STRIDE, XOFS+cellxpos[c],YOFS+cellypos[r], CELL_WIDTH,CELL_HEIGHT); } } rb->lcd_update_rect(cellxpos[c],cellypos[r],CELL_WIDTH,CELL_HEIGHT); } void display_board(struct sudoku_state_t* state) { int r,c; /* Clear the display buffer */ rb->lcd_clear_display(); /* Draw the gridlines - differently for different targets */ #if LCD_HEIGHT > 64 /* Large targets - draw single/double lines */ for (r=0;r<9;r++) { rb->lcd_hline(XOFS,XOFS+BOARD_WIDTH-1,YOFS+cellypos[r]-1); rb->lcd_vline(XOFS+cellxpos[r]-1,YOFS,YOFS+BOARD_HEIGHT-1); if ((r % 3)==0) { rb->lcd_hline(XOFS,XOFS+BOARD_WIDTH-1,YOFS+cellypos[r]-2); rb->lcd_vline(XOFS+cellxpos[r]-2,YOFS,YOFS+BOARD_HEIGHT-1); } } rb->lcd_hline(XOFS,XOFS+BOARD_WIDTH-1,YOFS+cellypos[8]+CELL_HEIGHT); rb->lcd_hline(XOFS,XOFS+BOARD_WIDTH-1,YOFS+cellypos[8]+CELL_HEIGHT+1); rb->lcd_vline(XOFS+cellxpos[8]+CELL_WIDTH,YOFS,YOFS+BOARD_HEIGHT-1); rb->lcd_vline(XOFS+cellxpos[8]+CELL_WIDTH+1,YOFS,YOFS+BOARD_HEIGHT-1); #elif (LCD_HEIGHT==64) /* Small targets - draw dotted/single lines */ for (r=0;r<9;r++) { if ((r % 3)==0) { /* Solid Line */ rb->lcd_hline(XOFS,XOFS+BOARD_WIDTH-1,YOFS+cellypos[r]-1); rb->lcd_vline(XOFS+cellxpos[r]-1,YOFS,YOFS+BOARD_HEIGHT-1); } else { /* Dotted line */ for (c=XOFS;clcd_drawpixel(c,YOFS+cellypos[r]-1); } for (c=YOFS;clcd_drawpixel(XOFS+cellxpos[r]-1,c); } } } rb->lcd_hline(XOFS,XOFS+BOARD_WIDTH-1,YOFS+cellypos[8]+CELL_HEIGHT); rb->lcd_vline(XOFS+cellxpos[8]+CELL_WIDTH,YOFS,YOFS+BOARD_HEIGHT-1); #else #error SUDOKU: Unsupported LCD height #endif #ifdef SUDOKU_BUTTON_POSSIBLE rb->lcd_vline(XOFSSCRATCHPAD,YOFS,YOFS+BOARD_HEIGHT-1); rb->lcd_vline(XOFSSCRATCHPAD+CELL_WIDTH+1,YOFS,YOFS+BOARD_HEIGHT-1); for (r=0;r<9;r++) { #if LCD_HEIGHT > 64 /* Large targets - draw single/double lines */ rb->lcd_hline(XOFSSCRATCHPAD,XOFSSCRATCHPAD+CELL_WIDTH+1, YOFS+cellypos[r]-1); if ((r % 3)==0) rb->lcd_hline(XOFSSCRATCHPAD,XOFSSCRATCHPAD+CELL_WIDTH+1, YOFS+cellypos[r]-2); #elif LCD_HEIGHT == 64 /* Small targets - draw dotted/single lines */ if ((r % 3)==0) { /* Solid Line */ rb->lcd_hline(XOFSSCRATCHPAD,XOFSSCRATCHPAD+CELL_WIDTH+1, YOFS+cellypos[r]-1); } else { /* Dotted line */ for (c=XOFSSCRATCHPAD;clcd_drawpixel(c,YOFS+cellypos[r]-1); } } #endif if ((r>0) && state->possiblevals[state->y][state->x]&(1<<(r))) rb->lcd_bitmap_part(sudoku_normal,0,BITMAP_HEIGHT*r,BITMAP_STRIDE, XOFSSCRATCHPAD+1,YOFS+cellypos[r-1], CELL_WIDTH,CELL_HEIGHT); } rb->lcd_hline(XOFSSCRATCHPAD,XOFSSCRATCHPAD+CELL_WIDTH+1, YOFS+cellypos[8]+CELL_HEIGHT); #if LCD_HEIGHT > 64 rb->lcd_hline(XOFSSCRATCHPAD,XOFSSCRATCHPAD+CELL_WIDTH+1, YOFS+cellypos[8]+CELL_HEIGHT+1); #endif if (state->possiblevals[state->y][state->x]&(1<<(r))) rb->lcd_bitmap_part(sudoku_normal,0,BITMAP_HEIGHT*r,BITMAP_STRIDE, XOFSSCRATCHPAD+1,YOFS+cellypos[8], CELL_WIDTH,CELL_HEIGHT); #endif /* Draw the numbers */ for (r=0;r<9;r++) { for (c=0;c<9;c++) { /* We have four types of cell: 1) User-entered number 2) Starting number 3) Cursor in cell */ if ((r==state->y) && (c==state->x)) { rb->lcd_bitmap_part(sudoku_inverse,0, BITMAP_HEIGHT*(state->currentboard[r][c]- '0'), BITMAP_STRIDE, XOFS+cellxpos[c],YOFS+cellypos[r], CELL_WIDTH,CELL_HEIGHT); } else { if (state->startboard[r][c]!='0') { rb->lcd_bitmap_part(sudoku_start,0, BITMAP_HEIGHT*(state->startboard[r][c]- '0'), BITMAP_STRIDE, XOFS+cellxpos[c],YOFS+cellypos[r], CELL_WIDTH,CELL_HEIGHT); } else { rb->lcd_bitmap_part(sudoku_normal,0, BITMAP_HEIGHT* (state->currentboard[r][c]-'0'), BITMAP_STRIDE, XOFS+cellxpos[c],YOFS+cellypos[r], CELL_WIDTH,CELL_HEIGHT); } } } } /* update the screen */ rb->lcd_update(); } /* Check the status of the board, assuming a change at the cursor location */ bool check_status(struct sudoku_state_t* state) { int check[9]; int r,c; int r1,c1; int cell; /* First, check the column */ for (cell=0;cell<9;cell++) { check[cell]=0; } for (r=0;r<9;r++) { cell=state->currentboard[r][state->x]; if (cell!='0') { if (check[cell-'1']==1) { return true; } check[cell-'1']=1; } } /* Second, check the row */ for (cell=0;cell<9;cell++) { check[cell]=0; } for (c=0;c<9;c++) { cell=state->currentboard[state->y][c]; if (cell!='0') { if (check[cell-'1']==1) { return true; } check[cell-'1']=1; } } /* Finally, check the 3x3 sub-grid */ for (cell=0;cell<9;cell++) { check[cell]=0; } r1=(state->y/3)*3; c1=(state->x/3)*3; for (r=r1;rcurrentboard[r][c]; if (cell!='0') { if (check[cell-'1']==1) { return true; } check[cell-'1']=1; } } } /* We passed all the checks :) */ return false; } void sudoku_generate(struct sudoku_state_t* state) { char* difficulty; char str[80]; clear_state(state); display_board(state); rb->splash(0, true, "Generating..."); #if !defined(SIMULATOR) && defined(HAVE_ADJUSTABLE_CPU_FREQ) rb->cpu_boost(true); #endif sudoku_generate_board(state,&difficulty); #if !defined(SIMULATOR) && defined(HAVE_ADJUSTABLE_CPU_FREQ) rb->cpu_boost(false); #endif rb->snprintf(str,sizeof(str),"Difficulty: %s",difficulty); display_board(state); rb->splash(3*HZ, true, str); rb->strncpy(state->filename,GAME_FILE,MAX_PATH); } int sudoku_menu_cb(int key, int m) { (void)m; switch(key) { #ifdef MENU_ENTER2 case MENU_ENTER2: #endif case MENU_ENTER: key = BUTTON_NONE; /* eat the downpress, next menu reacts on release */ break; #ifdef MENU_ENTER2 case MENU_ENTER2 | BUTTON_REL: #endif case MENU_ENTER | BUTTON_REL: key = MENU_ENTER; /* fake downpress, next menu doesn't like release */ break; } return key; } bool sudoku_menu(struct sudoku_state_t* state) { int m; int result; static const struct menu_item items[] = { { "Audio Playback", NULL }, { "Save", NULL }, { "Reload", NULL }, { "Clear", NULL }, { "Solve", NULL }, { "Generate", NULL }, { "New", NULL }, { "Quit", NULL }, }; m = rb->menu_init(items, sizeof(items) / sizeof(*items), sudoku_menu_cb, NULL, NULL, NULL); result=rb->menu_show(m); switch (result) { case 0: /* Audio playback */ playback_control(rb); break; case 1: /* Save state */ save_sudoku(state); break; case 2: /* Restore state */ restore_state(state); break; case 3: /* Clear all */ clear_board(state); break; case 4: /* Solve */ sudoku_solve(state); break; case 5: /* Generate Game */ sudoku_generate(state); break; case 6: /* Create a new game manually */ clear_state(state); state->editmode=1; break; case 7: /* Quit */ save_sudoku(state); rb->menu_exit(m); return true; break; default: break; } rb->menu_exit(m); return (result==MENU_ATTACHED_USB); } void move_cursor(struct sudoku_state_t* state, int newx, int newy) { int oldx, oldy; /* Check that the character at the cursor position is legal */ if (check_status(state)) { rb->splash(HZ*2, true, "Illegal move!"); /* Ignore any button presses during the splash */ rb->button_clear_queue(); return; } /* Move Cursor */ oldx=state->x; oldy=state->y; state->x=newx; state->y=newy; /* Redraw current and old cells */ update_cell(state,oldx,oldy); update_cell(state,newx,newy); } /* plugin entry point */ enum plugin_status plugin_start(struct plugin_api* api, void* parameter) { bool exit; int button; int lastbutton = BUTTON_NONE; long ticks; struct sudoku_state_t state; /* plugin init */ rb = api; /* end of plugin init */ clear_state(&state); if (parameter==NULL) { /* We have been started as a plugin - try default sudoku.ss */ if (!load_sudoku(&state,GAME_FILE)) { /* No previous game saved, generate one */ sudoku_generate(&state); } } else { if (!load_sudoku(&state,(char*)parameter)) { rb->splash(HZ*2, true, "Load error"); return(PLUGIN_ERROR); } } display_board(&state); /* The main game loop */ exit=false; ticks=0; while(!exit) { button = rb->button_get(true); switch(button){ #ifdef SUDOKU_BUTTON_QUIT /* Exit game */ case SUDOKU_BUTTON_QUIT: exit=1; break; #endif /* Increment digit */ #ifdef SUDOKU_BUTTON_ALTTOGGLE case SUDOKU_BUTTON_ALTTOGGLE | BUTTON_REPEAT: #endif case SUDOKU_BUTTON_TOGGLE | BUTTON_REPEAT: /* Slow down the repeat speed to 1/3 second */ if ((*rb->current_tick-ticks) < (HZ/3)) { break; } #ifdef SUDOKU_BUTTON_ALTTOGGLE case SUDOKU_BUTTON_ALTTOGGLE: #endif case SUDOKU_BUTTON_TOGGLE: #ifdef SUDOKU_BUTTON_TOGGLE_PRE if ((button == SUDOKU_BUTTON_TOGGLE) && (lastbutton != SUDOKU_BUTTON_TOGGLE_PRE)) break; #endif /* Increment digit */ ticks=*rb->current_tick; if (state.editmode) { if (state.startboard[state.y][state.x]=='9') { state.startboard[state.y][state.x]='0'; state.currentboard[state.y][state.x]='0'; } else { state.startboard[state.y][state.x]++; state.currentboard[state.y][state.x]++; } } else { if (state.startboard[state.y][state.x]=='0') { if (state.currentboard[state.y][state.x]=='9') { state.currentboard[state.y][state.x]='0'; } else { state.currentboard[state.y][state.x]++; } } } update_cell(&state,state.y,state.x); break; #ifdef SUDOKU_BUTTON_TOGGLEBACK case SUDOKU_BUTTON_TOGGLEBACK | BUTTON_REPEAT: /* Slow down the repeat speed to 1/3 second */ if ((*rb->current_tick-ticks) < (HZ/3)) { break; } case SUDOKU_BUTTON_TOGGLEBACK: /* Decrement digit */ ticks=*rb->current_tick; if (state.editmode) { if (state.startboard[state.y][state.x]=='0') { state.startboard[state.y][state.x]='9'; state.currentboard[state.y][state.x]='9'; } else { state.startboard[state.y][state.x]--; state.currentboard[state.y][state.x]--; } } else { if (state.startboard[state.y][state.x]=='0') { if (state.currentboard[state.y][state.x]=='0') { state.currentboard[state.y][state.x]='9'; } else { state.currentboard[state.y][state.x]--; } } } update_cell(&state,state.y,state.x); break; #endif /* move cursor left */ case SUDOKU_BUTTON_LEFT: case (SUDOKU_BUTTON_LEFT | BUTTON_REPEAT): if (state.x==0) { #ifndef SUDOKU_BUTTON_UP if (state.y==0) { move_cursor(&state,8,8); } else { move_cursor(&state,8,state.y-1); } #else move_cursor(&state,8,state.y); #endif } else { move_cursor(&state,state.x-1,state.y); } break; /* move cursor right */ case SUDOKU_BUTTON_RIGHT: case (SUDOKU_BUTTON_RIGHT | BUTTON_REPEAT): if (state.x==8) { #ifndef SUDOKU_BUTTON_DOWN if (state.y==8) { move_cursor(&state,0,0); } else { move_cursor(&state,0,state.y+1); } #else move_cursor(&state,0,state.y); #endif } else { move_cursor(&state,state.x+1,state.y); } break; #ifdef SUDOKU_BUTTON_UP /* move cursor up */ case SUDOKU_BUTTON_UP: case (SUDOKU_BUTTON_UP | BUTTON_REPEAT): if (state.y==0) { move_cursor(&state,state.x,8); } else { move_cursor(&state,state.x,state.y-1); } break; #endif #ifdef SUDOKU_BUTTON_DOWN /* move cursor down */ case SUDOKU_BUTTON_DOWN: case (SUDOKU_BUTTON_DOWN | BUTTON_REPEAT): if (state.y==8) { move_cursor(&state,state.x,0); } else { move_cursor(&state,state.x,state.y+1); } break; #endif case SUDOKU_BUTTON_MENU: #ifdef SUDOKU_BUTTON_MENU_PRE if (lastbutton != SUDOKU_BUTTON_MENU_PRE) break; #endif /* Don't let the user leave a game in a bad state */ if (check_status(&state)) { rb->splash(HZ*2, true, "Illegal move!"); /* Ignore any button presses during the splash */ rb->button_clear_queue(); } else { if (state.editmode) { rb->kbd_input(state.filename,MAX_PATH); if (save_sudoku(&state)) { state.editmode=0; } else { rb->splash(HZ*2, true, "Save failed"); } } else { if (sudoku_menu(&state)) { return PLUGIN_USB_CONNECTED; } } } break; #ifdef SUDOKU_BUTTON_POSSIBLE case SUDOKU_BUTTON_POSSIBLE: /* Toggle current number in the possiblevals structure */ if (state.currentboard[state.y][state.x]!='0') { state.possiblevals[state.y][state.x]^= (1 << (state.currentboard[state.y][state.x] - '0')); } break; #endif default: if (rb->default_event_handler(button) == SYS_USB_CONNECTED) { /* Quit if USB has been connected */ return PLUGIN_USB_CONNECTED; } break; } if (button != BUTTON_NONE) lastbutton = button; display_board(&state); } return PLUGIN_OK; } #endif