#include #include #include #include #include #include "gr-sim.h" #include "tfv_utils.h" #include "tfv_zp.h" #include "tfv_sprites.h" /* Mode7 code based on code from: */ /* http://www.helixsoft.nl/articles/circle/sincos.htm */ static unsigned char flying_map[64]= { 2,15,15,15, 15,15,15, 2, 13,12,12, 8, 4, 4, 0,13, 13,12,12,12, 8, 4, 4,13, 13,12,12, 8, 4, 4, 4,13, 13,12, 9, 9, 8, 4, 4,13, 13,12, 9, 8, 4, 4, 4,13, 13,12, 9, 9, 1, 4, 4,13, 2,13,13,13, 13,13,13, 2}; static unsigned char water_map[32]={ 2,2,2,2, 2,2,2,2, 14,2,2,2, 2,2,2,2, 2, 2,2,2, 2,2,2,2, 2,2,2,2, 14,2,2,2, }; #define TILE_W 64 #define TILE_H 64 #define MASK_X (TILE_W - 1) #define MASK_Y (TILE_H - 1) #define LOWRES_W 40 #define LOWRES_H 40 static int displayed=0; static int over_water=0; static int lookup_map(int xx, int yy) { int color,offset; color=2; xx=xx&MASK_X; yy=yy&MASK_Y; if (!displayed) { printf("XX,YY! %x,%x\n",xx,yy); } // if ( ((y&0x3)==1) && ((x&7)==0) ) color=14; // if ( ((y&0x3)==3) && ((x&7)==4) ) color=14; offset=yy<<3; offset+=xx; // color=water_map[((yy*8)+xx)&0x1f]; color=water_map[offset&0x1f]; /* 2 2 2 2 2 2 2 2 */ /* e 2 2 2 2 2 2 2 */ /* 2 2 2 2 2 2 2 2 */ /* 2 2 2 2 e 2 2 2 */ if ((yy<8) && (xx<8)) { color=flying_map[offset]; } if (!displayed) { printf("COLOR! %x\n",color); } return color; } // current screen position static int screen_x, screen_y; static char angle=1; // Speed #define SPEED_STOPPED 0 static unsigned char speed=SPEED_STOPPED; // 0..4, with 0=stopped // map coordinates double dx,dy; double cx=0.0,cy=0.0; static double space_z=4.5; // height of the camera above the plane static int horizon=-2; // number of pixels line 0 is below the horizon static double scale_x=20, scale_y=20; double factor; double BETA=-0.5; #define ANGLE_STEPS 32 double our_sin(unsigned char angle) { double r; r=3.14159265358979*2.0*(double)angle/(double)ANGLE_STEPS; return sin(r); } double our_cos(unsigned char angle) { double r; r=3.14159265358979*2.0*(double)angle/(double)ANGLE_STEPS; return cos(r); } // // Detailed version // // void draw_background_mode7(void) { // the distance and horizontal scale of the line we are drawing double distance, horizontal_scale; // step for points in space between two pixels on a horizontal line double line_dx, line_dy; // current space position double space_x, space_y; int map_color; over_water=0; /* Draw Sky */ /* Originally wanted to be fancy and have sun too, but no */ color_equals(COLOR_MEDIUMBLUE); for(screen_y=0;screen_y<6;screen_y+=2) { hlin_double(ram[DRAW_PAGE], 0, 40, screen_y); } /* Draw hazy horizon */ color_equals(COLOR_GREY); hlin_double(ram[DRAW_PAGE], 0, 40, 6); // Move camera back a bit factor=space_z*BETA; printf("space_z=%lf BETA=%lf factor=%lf\n",space_z,BETA,factor); for (screen_y = 8; screen_y < LOWRES_H; screen_y++) { // first calculate the distance of the line we are drawing distance = (space_z * scale_y) / (screen_y + horizon); // then calculate the horizontal scale, or the distance between // space points on this horizontal line horizontal_scale = (distance / scale_x); // calculate the dx and dy of points in space when we step // through all points on this line line_dx = -our_sin(angle) * horizontal_scale; line_dy = our_cos(angle) * horizontal_scale; // calculate the starting position space_x = cx + ((distance+factor) * our_cos(angle)) - LOWRES_W/2 * line_dx; space_y = cy + ((distance+factor) * our_sin(angle)) - LOWRES_W/2 * line_dy; // go through all points in this screen line for (screen_x = 0; screen_x < LOWRES_W-1; screen_x++) { // get a pixel from the tile and put it on the screen map_color=lookup_map((int)space_x,(int)space_y); color_equals(map_color); if ((screen_x==20) && (screen_y==38)) { if (map_color==COLOR_DARKBLUE) over_water=1; } plot(screen_x,screen_y); // advance to the next position in space space_x += line_dx; space_y += line_dy; } } } #define SHIPX 15 int flying(void) { unsigned char ch; int shipy; int turning=0; int draw_splash=0,splash_count=0; int zint; /************************************************/ /* Flying */ /************************************************/ gr(); ram[DRAW_PAGE]=PAGE0; clear_bottom(); ram[DRAW_PAGE]=PAGE1; clear_bottom(); shipy=20; while(1) { if (splash_count>0) splash_count--; ch=grsim_input(); if ((ch=='q') || (ch==27)) break; #if 0 if (ch=='g') { BETA+=0.1; printf("Horizon=%lf\n",BETA); } if (ch=='h') { BETA-=0.1; printf("Horizon=%lf\n",BETA); } if (ch=='s') { scale_x++; scale_y++; printf("Scale=%lf\n",scale_x); } #endif if ((ch=='w') || (ch==APPLE_UP)) { if (shipy>16) { shipy-=2; space_z+=1; } splash_count=0; // printf("Z=%lf\n",space_z); } if ((ch=='s') || (ch==APPLE_DOWN)) { if (shipy<28) { shipy+=2; space_z-=1; } else { splash_count=10; } // printf("Z=%lf\n",space_z); } if ((ch=='a') || (ch==APPLE_LEFT)) { if (turning>0) { turning=0; } else { turning=-20; angle-=1; if (angle<0) angle+=ANGLE_STEPS; } } if ((ch=='d') || (ch==APPLE_RIGHT)) { if (turning<0) { turning=0; } else { turning=20; angle+=1; if (angle>=ANGLE_STEPS) angle-=ANGLE_STEPS; } } /* Used to be able to go backwards */ if (ch=='z') { if (speed<3) speed++; } if (ch=='x') { if (speed>0) speed--; } if (ch==' ') { speed=SPEED_STOPPED; } if (ch=='h') { print_help(); } /* Ending */ if (ch==13) { int landing_color,tx,ty; tx=cx; ty=cy; landing_color=lookup_map(tx,ty); printf("Trying to land at %d %d\n",tx,ty); printf("Color=%d\n",landing_color); if (landing_color==12) { int loop; zint=space_z; /* Land the ship */ for(loop=zint;loop>0;loop--) { draw_background_mode7(); grsim_put_sprite(shadow_forward,SHIPX+3,31+zint); grsim_put_sprite(ship_forward,SHIPX,shipy); page_flip(); usleep(200000); space_z--; } return 0; } else { htab(11); vtab(22); move_cursor(); print_both_pages("NEED TO LAND ON GRASS!"); } } if (speed!=SPEED_STOPPED) { dx = (double)speed * 0.25 * our_cos (angle); dy = (double)speed * 0.25 * our_sin (angle); cx += dx; cy += dy; } draw_background_mode7(); zint=space_z; draw_splash=0; if (speed>0) { if ((shipy>25) && (turning!=0)) { splash_count=1; } if ((over_water) && (splash_count)) { draw_splash=1; } } // printf("VMW: %d %d\n",draw_splash,splash_count); if (turning==0) { if (draw_splash) { grsim_put_sprite(splash_forward, SHIPX+1,shipy+9); } grsim_put_sprite(shadow_forward,SHIPX+3,31+zint); grsim_put_sprite(ship_forward,SHIPX,shipy); } if (turning<0) { if (draw_splash) { grsim_put_sprite(splash_left, SHIPX+1,36); } grsim_put_sprite(shadow_left,SHIPX+3,31+zint); grsim_put_sprite(ship_left,SHIPX,shipy); turning++; } if (turning>0) { if (draw_splash) { grsim_put_sprite(splash_right, SHIPX+1,36); } grsim_put_sprite(shadow_right,SHIPX+3,31+zint); grsim_put_sprite(ship_right,SHIPX,shipy); turning--; } page_flip(); usleep(20000); } return 0; }