/** @file main.c Main source file of the game that puts together all the pieces. main game logic is implemented here. by Miloslav Ciz (drummyfish), 2019 Released under CC0 1.0 (https://creativecommons.org/publicdomain/zero/1.0/) plus a waiver of all other intellectual property. The goal of this work is be and remain completely in the public domain forever, available for any use whatsoever. */ #include /* The following keys are mandatory to be implemented on any platform in order for the game to be playable. */ #define SFG_KEY_UP 0 #define SFG_KEY_RIGHT 1 #define SFG_KEY_DOWN 2 #define SFG_KEY_LEFT 3 #define SFG_KEY_A 4 #define SFG_KEY_B 5 #define SFG_KEY_C 6 /* The following keys are optional for a platform to implement. They just make the controls more comfortable. */ #define SFG_KEY_JUMP 7 #define SFG_KEY_STRAFE_LEFT 8 #define SFG_KEY_STRAFE_RIGHT 9 #define SFG_KEY_MAP 10 /* ============================= PORTING =================================== */ /* When porting, do the following: - implement the following functions in your platform_*.h. - Call SFG_init() from your platform initialization code. - Call SFG_mainLoopBody() from within your platform's main loop. - include "settings.h" in your platform_*.h and optionally hard-override (redefine) some settings in platform_*.h, according to the platform's needs. */ #define SFG_LOG(str) ; ///< Can be redefined to log messages for better debug. #define SFG_PROGRAM_MEMORY static const /**< Can be redefined to platform's specifier of program meory. */ /** Return 1 (0) if given key is pressed (not pressed). At least the mandatory keys have to be implemented, the optional keys don't have to ever return 1. See the key contant definitions to see which ones are mandatory. */ int8_t SFG_keyPressed(uint8_t key); /** Return time in ms sice program start. */ uint32_t SFG_getTimeMs(); /** Sleep (yield CPU) for specified amount of ms. This is used to relieve CPU usage. If your platform doesn't need this or handles it in other way, this function can do nothing. */ void SFG_sleepMs(uint16_t timeMs); /** Set specified screen pixel. The function doesn't have to check whether the coordinates are within screen. */ static inline void SFG_setPixel(uint16_t x, uint16_t y, uint8_t colorIndex); /* ========================================================================= */ /** Game main loop body, call this inside the platform's specific main loop. */ void SFG_mainLoopBody(); /** Initializes the whole program, call this in the platform initialization. */ void SFG_init(); #ifdef SFG_PLATFORM_POKITTO #include "platform_pokitto.h" #else #include "platform_sdl.h" #endif #include "constants.h" #include "levels.h" #include "assets.h" #include "palette.h" #include "settings.h" // will include if not included by platform #define RCL_PIXEL_FUNCTION SFG_pixelFunc #define RCL_TEXTURE_VERTICAL_STRETCH 0 #define RCL_CAMERA_COLL_HEIGHT_BELOW 800 #define RCL_CAMERA_COLL_HEIGHT_ABOVE 100 #include "raycastlib.h" #define SFG_GAME_RESOLUTION_X \ (SFG_SCREEN_RESOLUTION_X / SFG_RESOLUTION_SCALEDOWN) #define SFG_GAME_RESOLUTION_Y \ (SFG_SCREEN_RESOLUTION_Y / SFG_RESOLUTION_SCALEDOWN) #define SFG_MS_PER_FRAME (1000 / SFG_FPS) // ms per frame with target FPS #if SFG_MS_PER_FRAME == 0 #define SFG_MS_PER_FRAME 1 #endif #define SFG_PLAYER_TURN_UNITS_PER_FRAME \ ((SFG_PLAYER_TURN_SPEED * RCL_UNITS_PER_SQUARE) / (360 * SFG_FPS)) #if SFG_PLAYER_TURN_UNITS_PER_FRAME == 0 #define SFG_PLAYER_TURN_UNITS_PER_FRAME 1 #endif #define SFG_PLAYER_MOVE_UNITS_PER_FRAME \ ((SFG_PLAYER_MOVE_SPEED * RCL_UNITS_PER_SQUARE) / SFG_FPS) #if SFG_PLAYER_MOVE_UNITS_PER_FRAME == 0 #define SFG_PLAYER_MOVE_UNITS_PER_FRAME 1 #endif #define SFG_GRAVITY_SPEED_INCREASE_PER_FRAME \ ((SFG_GRAVITY_ACCELERATION * RCL_UNITS_PER_SQUARE) / (SFG_FPS * SFG_FPS)) #if SFG_GRAVITY_SPEED_INCREASE_PER_FRAME == 0 #define SFG_GRAVITY_SPEED_INCREASE_PER_FRAME 1 #endif #define SFG_HEADBOB_FRAME_INCREASE_PER_FRAME \ (SFG_HEADBOB_SPEED / SFG_FPS) #if SFG_HEADBOB_FRAME_INCREASE_PER_FRAME == 0 #define SFG_HEADBOB_FRAME_INCREASE_PER_FRAME 1 #endif #define SFG_HEADBOB_ENABLED (SFG_HEADBOB_SPEED > 0 && SFG_HEADBOB_OFFSET > 0) uint8_t SFG_zBuffer[SFG_GAME_RESOLUTION_X]; #define SFG_RCL_UNIT_TO_Z_BUFFER(x) (x / RCL_UNITS_PER_SQUARE) /** Step in which walls get higher, in raycastlib units. */ #define SFG_WALL_HEIGHT_STEP (RCL_UNITS_PER_SQUARE / 4) #define SFG_CEILING_MAX_HEIGHT\ (16 * RCL_UNITS_PER_SQUARE - RCL_UNITS_PER_SQUARE / 2 ) int8_t SFG_backgroundScaleMap[SFG_GAME_RESOLUTION_Y]; uint16_t SFG_backgroundScroll; struct { RCL_Camera camera; int8_t squarePosition[2]; RCL_Vector2D direction; RCL_Unit verticalSpeed; RCL_Unit previousVerticalSpeed; /**< Vertical speed in previous frame, needed for determining whether player is in the air. */ uint16_t headBobFrame; } SFG_player; #if SFG_RESOLUTION_SCALEDOWN == 1 #define SFG_setGamePixel SFG_setPixel #else /** Sets the game pixel (a pixel that can potentially be bigger than the screen pixel). */ static inline void SFG_setGamePixel(uint16_t x, uint16_t y, uint8_t colorIndex) { uint16_t screenY = y * SFG_RESOLUTION_SCALEDOWN; uint16_t screenX = x * SFG_RESOLUTION_SCALEDOWN; for (uint16_t j = screenY; j < screenY + SFG_RESOLUTION_SCALEDOWN; ++j) for (uint16_t i = screenX; i < screenX + SFG_RESOLUTION_SCALEDOWN; ++i) SFG_setPixel(i,j,colorIndex); } #endif void SFG_recompurePLayerDirection() { SFG_player.camera.direction = RCL_wrap(SFG_player.camera.direction,RCL_UNITS_PER_SQUARE); SFG_player.direction = RCL_angleToDirection(SFG_player.camera.direction); SFG_player.direction.x = (SFG_player.direction.x * SFG_PLAYER_MOVE_UNITS_PER_FRAME) / RCL_UNITS_PER_SQUARE; SFG_player.direction.y = (SFG_player.direction.y * SFG_PLAYER_MOVE_UNITS_PER_FRAME) / RCL_UNITS_PER_SQUARE; SFG_backgroundScroll = ((SFG_player.camera.direction * 8) * SFG_GAME_RESOLUTION_Y) / RCL_UNITS_PER_SQUARE; } void SFG_initPlayer() { RCL_initCamera(&SFG_player.camera); SFG_player.camera.resolution.x = SFG_GAME_RESOLUTION_X / SFG_RAYCASTING_SUBSAMPLE; SFG_player.camera.resolution.y = SFG_GAME_RESOLUTION_Y; SFG_player.camera.height = RCL_UNITS_PER_SQUARE * 12; SFG_player.camera.position.x = RCL_UNITS_PER_SQUARE * 15; SFG_player.camera.position.y = RCL_UNITS_PER_SQUARE * 8; SFG_recompurePLayerDirection(); SFG_player.verticalSpeed = 0; SFG_player.previousVerticalSpeed = 0; SFG_player.headBobFrame = 0; } RCL_RayConstraints SFG_rayConstraints; typedef struct { uint8_t coords[2]; uint8_t state; /**< door state in format: MSB ccbaaaaa LSB aaaaa: current door height (how much they're open) b: whether currently going up (0) or down (1) cc: by which keys the door is unlocked */ } SFG_DoorRecord; #define SFG_DOOR_DEFAULT_STATE 0x1f #define SFG_DOOR_UP_DOWN_MASK 0x20 #define SFG_DOOR_VERTICAL_POSITION_MASK 0x1f #define SFG_DOOR_HEIGHT_STEP (RCL_UNITS_PER_SQUARE / 0x1f) #define SFG_DOOR_INCREMENT_PER_FRAME \ (SFG_DOOR_OPEN_SPEED / (SFG_DOOR_HEIGHT_STEP * SFG_FPS)) #if SFG_DOOR_INCREMENT_PER_FRAME == 0 #define SFG_DOOR_INCREMENT_PER_FRAME 1 #endif #define SFG_MAX_DOORS 32 /** Holds information about one instance of a level item (a type of level element, e.g. pickable items, decorations etc.). The format is following: MSB abbbbbbb LSB a: active flag, 1 means the item is nearby to player and is active bbbbbbb: index to elements array of the current level, pointing to element representing this item */ typedef uint8_t SFG_ItemRecord; #define SFG_ITEM_RECORD_ACTIVE_MASK 0x80 #define SFG_MAX_LEVEL_ITEMS SFG_MAX_LEVEL_ELEMENTS /** Stores the current level and helper precomputed vaues for better performance. */ struct { const SFG_Level *levelPointer; const uint8_t* textures[7]; uint32_t timeStart; uint32_t frameStart; uint8_t floorColor; uint8_t ceilingColor; SFG_DoorRecord doorRecords[SFG_MAX_DOORS]; uint8_t doorRecordCount; uint8_t checkedDoorIndex; ///< Says which door are currently being checked. SFG_ItemRecord itemRecords[SFG_MAX_LEVEL_ITEMS]; ///< Holds level items uint8_t itemRecordCount; uint8_t checkedItemIndex; ///< Same as checkedDoorIndex, but for items. } SFG_currentLevel; #if SFG_DITHERED_SHADOW SFG_PROGRAM_MEMORY uint8_t SFG_ditheringPatterns[] = { 0,0,0,0, 0,0,0,0, 0,0,0,0, 0,1,0,0, 0,0,0,0, 0,1,0,1, 1,0,1,0, 0,1,0,0, 1,0,1,0, 0,1,0,1, 1,0,1,0, 0,1,1,1, 1,1,1,1, 0,1,0,1, 1,1,1,1, 0,1,1,1, 1,1,1,1, 1,1,1,1 }; #endif void SFG_pixelFunc(RCL_PixelInfo *pixel) { uint8_t color; uint8_t shadow = 0; if (pixel->position.y == SFG_GAME_RESOLUTION_Y / 2) SFG_zBuffer[pixel->position.x] = SFG_RCL_UNIT_TO_Z_BUFFER(pixel->depth); if (pixel->isHorizon && pixel->depth > RCL_UNITS_PER_SQUARE * 16) { color = SFG_TRANSPARENT_COLOR; } else if (pixel->isWall) { uint8_t textureIndex = pixel->isFloor ? ( ((pixel->hit.type & SFG_TILE_PROPERTY_MASK) != SFG_TILE_PROPERTY_DOOR) ? (pixel->hit.type & 0x7) : ( (pixel->texCoords.y > RCL_UNITS_PER_SQUARE) ? (pixel->hit.type & 0x7) : 255 ) ): ((pixel->hit.type & 0x38) >> 3); RCL_Unit textureV = pixel->texCoords.y; if ((pixel->hit.type & SFG_TILE_PROPERTY_MASK) == SFG_TILE_PROPERTY_SQUEEZER) textureV += pixel->wallHeight; color = textureIndex != SFG_TILE_TEXTURE_TRANSPARENT ? (SFG_getTexel( textureIndex != 255 ? SFG_currentLevel.textures[textureIndex]: SFG_texturesWall[SFG_currentLevel.levelPointer->doorTextureIndex], pixel->texCoords.x / 32, textureV / 32) ) : SFG_TRANSPARENT_COLOR; shadow = pixel->hit.direction >> 1; } else { color = pixel->isFloor ? (SFG_currentLevel.floorColor) : (pixel->height < SFG_CEILING_MAX_HEIGHT ? SFG_currentLevel.ceilingColor : SFG_TRANSPARENT_COLOR); } if (color != SFG_TRANSPARENT_COLOR) { #if SFG_DITHERED_SHADOW uint8_t fogShadow = (pixel->depth * 4) / (RCL_UNITS_PER_SQUARE); uint8_t fogShadowPart = fogShadow & 0x07; fogShadow /= 8; uint8_t xMod4 = pixel->position.x & 0x03; uint8_t yMod2 = pixel->position.y & 0x01; shadow += fogShadow + SFG_ditheringPatterns[fogShadowPart * 8 + yMod2 * 4 + xMod4]; #else shadow += pixel->depth / (RCL_UNITS_PER_SQUARE * 2); #endif #if SFG_ENABLE_FOG color = palette_minusValue(color,shadow); #endif } else { color = SFG_getTexel(SFG_backgrounds[0], SFG_backgroundScaleMap[(pixel->position.x * SFG_RAYCASTING_SUBSAMPLE + SFG_backgroundScroll) % SFG_GAME_RESOLUTION_Y], // ^ TODO: get rid of mod? SFG_backgroundScaleMap[pixel->position.y]); } RCL_Unit screenX = pixel->position.x * SFG_RAYCASTING_SUBSAMPLE; for (uint8_t i = 0; i < SFG_RAYCASTING_SUBSAMPLE; ++i) { SFG_setGamePixel(screenX,pixel->position.y,color); screenX++; } } #define SFG_MAX_SPRITE_SIZE SFG_GAME_RESOLUTION_X uint8_t SFG_spriteSamplingPoints[SFG_MAX_SPRITE_SIZE]; void SFG_drawScaledSprite( const uint8_t *image, int16_t centerX, int16_t centerY, int16_t size, uint8_t minusValue, RCL_Unit distance) { if ((size > SFG_MAX_SPRITE_SIZE) || (size == 0)) return; uint16_t halfSize = size / 2; int16_t topLeftX = centerX - halfSize; int16_t topLeftY = centerY - halfSize; int16_t x0, u0; if (topLeftX < 0) { u0 = -1 * topLeftX; x0 = 0; } else { u0 = 0; x0 = topLeftX; } int16_t x1 = topLeftX + size - 1; if (x1 >= SFG_GAME_RESOLUTION_X) x1 = SFG_GAME_RESOLUTION_X - 1; int16_t y0, v0; if (topLeftY < 0) { v0 = -1 * topLeftY; y0 = 0; } else { v0 = 0; y0 = topLeftY; } int16_t y1 = topLeftY + size - 1; if (y1 >= SFG_GAME_RESOLUTION_Y) y1 = SFG_GAME_RESOLUTION_Y - 1; if ((x0 > x1) || (y0 > y1) || (u0 >= size) || (v0 >= size)) return; // outside screen? int16_t u1 = u0 + (x1 - x0); int16_t v1 = v0 + (y1 - y0); // precompute sampling positions: int16_t uMin = RCL_min(u0,u1); int16_t vMin = RCL_min(v0,v1); int16_t uMax = RCL_max(u0,u1); int16_t vMax = RCL_max(v0,v1); int16_t precompFrom = RCL_min(uMin,vMin); int16_t precompTo = RCL_max(uMax,vMax); precompFrom = RCL_max(0,precompFrom); precompTo = RCL_min(SFG_MAX_SPRITE_SIZE - 1,precompTo); #define PRECOMP_SCALE 2048 int16_t precompStepScaled = (SFG_TEXTURE_SIZE * PRECOMP_SCALE) / size; int16_t precompPosScaled = precompFrom * precompStepScaled; for (int16_t i = precompFrom; i <= precompTo; ++i) { SFG_spriteSamplingPoints[i] = precompPosScaled / PRECOMP_SCALE; precompPosScaled += precompStepScaled; } #undef PRECOMP_SCALE uint8_t zDistance = SFG_RCL_UNIT_TO_Z_BUFFER(distance); for (int16_t x = x0, u = u0; x <= x1; ++x, ++u) { if (SFG_zBuffer[x] > zDistance) { int8_t columnTransparent = 1; for (int16_t y = y0, v = v0; y <= y1; ++y, ++v) { uint8_t color = SFG_getTexel(image,SFG_spriteSamplingPoints[u], SFG_spriteSamplingPoints[v]); if (color != SFG_TRANSPARENT_COLOR) { #if SFG_DIMINISH_SPRITES color = palette_minusValue(color,minusValue); #endif columnTransparent = 0; SFG_setGamePixel(x,y,color); } } if (!columnTransparent) SFG_zBuffer[x] = zDistance; } } } RCL_Unit SFG_texturesAt(int16_t x, int16_t y) { uint8_t p; SFG_TileDefinition tile = SFG_getMapTile(SFG_currentLevel.levelPointer,x,y,&p); return SFG_TILE_FLOOR_TEXTURE(tile) | (SFG_TILE_CEILING_TEXTURE(tile) << 3) | p; // ^ store both textures (floor and ceiling) and properties in one number } RCL_Unit SFG_movingWallHeight ( RCL_Unit low, RCL_Unit high, uint32_t time ) { RCL_Unit height = high - low; RCL_Unit halfHeight = height / 2; RCL_Unit sinArg = (time * ((SFG_MOVING_WALL_SPEED * RCL_UNITS_PER_SQUARE) / 1000)) / height; return low + halfHeight + (RCL_sinInt(sinArg) * halfHeight) / RCL_UNITS_PER_SQUARE; } uint32_t SFG_frameTime; ///< Keeps a constant time (in ms) during a frame RCL_Unit SFG_floorHeightAt(int16_t x, int16_t y) { uint8_t properties; SFG_TileDefinition tile = SFG_getMapTile(SFG_currentLevel.levelPointer,x,y,&properties); uint8_t doorHeight = 0; if (properties == SFG_TILE_PROPERTY_DOOR) { for (uint8_t i = 0; i < SFG_currentLevel.doorRecordCount; ++i) { SFG_DoorRecord *door = &(SFG_currentLevel.doorRecords[i]); if ((door->coords[0] == x) && (door->coords[1] == y)) { doorHeight = door->state & SFG_DOOR_VERTICAL_POSITION_MASK; break; } } } else if (properties == SFG_TILE_PROPERTY_ELEVATOR) { return SFG_movingWallHeight( SFG_TILE_FLOOR_HEIGHT(tile) * SFG_WALL_HEIGHT_STEP, SFG_TILE_CEILING_HEIGHT(tile) * SFG_WALL_HEIGHT_STEP, SFG_frameTime - SFG_currentLevel.timeStart); } return SFG_TILE_FLOOR_HEIGHT(tile) * SFG_WALL_HEIGHT_STEP - doorHeight * SFG_DOOR_HEIGHT_STEP; } RCL_Unit SFG_ceilingHeightAt(int16_t x, int16_t y) { uint8_t properties; SFG_TileDefinition tile = SFG_getMapTile(SFG_currentLevel.levelPointer,x,y,&properties); if (properties == SFG_TILE_PROPERTY_ELEVATOR) return SFG_CEILING_MAX_HEIGHT; uint8_t height = SFG_TILE_CEILING_HEIGHT(tile); return properties != SFG_TILE_PROPERTY_SQUEEZER ? ( height != SFG_TILE_CEILING_MAX_HEIGHT ? ((SFG_TILE_FLOOR_HEIGHT(tile) + height) * SFG_WALL_HEIGHT_STEP) : SFG_CEILING_MAX_HEIGHT ) : SFG_movingWallHeight( SFG_TILE_FLOOR_HEIGHT(tile) * SFG_WALL_HEIGHT_STEP, (SFG_TILE_CEILING_HEIGHT(tile) + SFG_TILE_FLOOR_HEIGHT(tile)) * SFG_WALL_HEIGHT_STEP, SFG_frameTime - SFG_currentLevel.timeStart); } uint32_t SFG_gameFrame; uint32_t SFG_lastFrameTimeMs; void SFG_setAndInitLevel(const SFG_Level *level) { SFG_LOG("setting and initializing level"); SFG_currentLevel.levelPointer = level; SFG_currentLevel.floorColor = level->floorColor; SFG_currentLevel.ceilingColor = level->ceilingColor; for (uint8_t i = 0; i < 7; ++i) SFG_currentLevel.textures[i] = SFG_texturesWall[level->textureIndices[i]]; SFG_LOG("initializing doors"); SFG_currentLevel.checkedDoorIndex = 0; SFG_currentLevel.doorRecordCount = 0; for (uint8_t j = 0; j < SFG_MAP_SIZE; ++j) { for (uint8_t i = 0; i < SFG_MAP_SIZE; ++i) { uint8_t properties; SFG_getMapTile(level,i,j,&properties); if ((properties & SFG_TILE_PROPERTY_MASK) == SFG_TILE_PROPERTY_DOOR) { SFG_DoorRecord *d = &(SFG_currentLevel.doorRecords[SFG_currentLevel.doorRecordCount]); d->coords[0] = i; d->coords[1] = j; d->state = SFG_DOOR_DEFAULT_STATE; SFG_currentLevel.doorRecordCount++; } if (SFG_currentLevel.doorRecordCount >= SFG_MAX_DOORS) break; } if (SFG_currentLevel.doorRecordCount >= SFG_MAX_DOORS) break; } SFG_LOG("initializing level elements"); SFG_currentLevel.checkedItemIndex = 0; SFG_currentLevel.itemRecordCount = 0; for (uint8_t i = 0; i < SFG_MAX_LEVEL_ELEMENTS; ++i) { const SFG_LevelElement *e = &(SFG_currentLevel.levelPointer->elements[i]); if (e->elementType == SFG_LEVEL_ELEMENT_BARREL) { SFG_currentLevel.itemRecords[SFG_currentLevel.itemRecordCount] = i; SFG_currentLevel.itemRecordCount++; } } SFG_currentLevel.timeStart = SFG_getTimeMs(); SFG_currentLevel.frameStart = SFG_gameFrame; SFG_initPlayer(); } void SFG_init() { SFG_LOG("initializing game") SFG_gameFrame = 0; RCL_initRayConstraints(&SFG_rayConstraints); SFG_rayConstraints.maxHits = SFG_RAYCASTING_MAX_HITS; SFG_rayConstraints.maxSteps = SFG_RAYCASTING_MAX_STEPS; for (uint16_t i = 0; i < SFG_GAME_RESOLUTION_Y; ++i) SFG_backgroundScaleMap[i] = (i * SFG_TEXTURE_SIZE) / SFG_GAME_RESOLUTION_Y; SFG_backgroundScroll = 0; SFG_setAndInitLevel(&SFG_level0); SFG_lastFrameTimeMs = SFG_getTimeMs(); } /** Performs one game step (logic, physics), happening SFG_MS_PER_FRAME after previous frame. */ void SFG_gameStep() { int8_t recomputeDirection = 0; RCL_Vector2D moveOffset; moveOffset.x = 0; moveOffset.y = 0; int8_t strafe = 0; if (SFG_keyPressed(SFG_KEY_A)) { if (SFG_keyPressed(SFG_KEY_LEFT)) strafe = -1; else if (SFG_keyPressed(SFG_KEY_RIGHT)) strafe = 1; } else { if (SFG_keyPressed(SFG_KEY_LEFT)) { SFG_player.camera.direction -= SFG_PLAYER_TURN_UNITS_PER_FRAME; recomputeDirection = 1; } else if (SFG_keyPressed(SFG_KEY_RIGHT)) { SFG_player.camera.direction += SFG_PLAYER_TURN_UNITS_PER_FRAME; recomputeDirection = 1; } if (recomputeDirection) SFG_recompurePLayerDirection(); } if (SFG_keyPressed(SFG_KEY_STRAFE_LEFT)) strafe = -1; else if (SFG_keyPressed(SFG_KEY_STRAFE_RIGHT)) strafe = 1; if (strafe != 0) { moveOffset.x = strafe * SFG_player.direction.y; moveOffset.y = -1 * strafe * SFG_player.direction.x; } #if SFG_PREVIEW_MODE if (SFG_keyPressed(SFG_KEY_B)) SFG_player.verticalSpeed = SFG_PLAYER_MOVE_UNITS_PER_FRAME; else if (SFG_keyPressed(SFG_KEY_C)) SFG_player.verticalSpeed = -1 * SFG_PLAYER_MOVE_UNITS_PER_FRAME; else SFG_player.verticalSpeed = 0; #else RCL_Unit verticalOffset = ( ( SFG_keyPressed(SFG_KEY_JUMP) || (SFG_keyPressed(SFG_KEY_UP) && SFG_keyPressed(SFG_KEY_C)) ) && (SFG_player.verticalSpeed == 0) && (SFG_player.previousVerticalSpeed == 0)) ? SFG_PLAYER_JUMP_SPEED : (SFG_player.verticalSpeed - SFG_GRAVITY_SPEED_INCREASE_PER_FRAME); #endif #if SFG_HEADBOB_ENABLED int8_t bobbing = 0; #endif if (SFG_keyPressed(SFG_KEY_UP)) { moveOffset.x += SFG_player.direction.x; moveOffset.y += SFG_player.direction.y; #if SFG_HEADBOB_ENABLED bobbing = 1; #endif } else if (SFG_keyPressed(SFG_KEY_DOWN)) { moveOffset.x -= SFG_player.direction.x; moveOffset.y -= SFG_player.direction.y; #if SFG_HEADBOB_ENABLED bobbing = 1; #endif } #if SFG_HEADBOB_ENABLED if (bobbing) { SFG_player.headBobFrame += SFG_HEADBOB_FRAME_INCREASE_PER_FRAME; } else if (SFG_player.headBobFrame != 0) { // smoothly stop bobbing uint8_t quadrant = (SFG_player.headBobFrame % RCL_UNITS_PER_SQUARE) / (RCL_UNITS_PER_SQUARE / 4); /* when in quadrant in which sin is going away from zero, switch to the same value of the next quadrant, so that bobbing starts to go towards zero immediately */ if (quadrant % 2 == 0) SFG_player.headBobFrame = ((quadrant + 1) * RCL_UNITS_PER_SQUARE / 4) + (RCL_UNITS_PER_SQUARE / 4 - SFG_player.headBobFrame % (RCL_UNITS_PER_SQUARE / 4)); RCL_Unit currentFrame = SFG_player.headBobFrame; RCL_Unit nextFrame = SFG_player.headBobFrame + 16; // only stop bobbing when we pass frame at which sin crosses ero SFG_player.headBobFrame = (currentFrame / (RCL_UNITS_PER_SQUARE / 2) == nextFrame / (RCL_UNITS_PER_SQUARE / 2)) ? nextFrame : 0; } #endif RCL_Unit previousHeight = SFG_player.camera.height; #if SFG_PREVIEW_MODE SFG_player.camera.position.x += SFG_PREVIEW_MODE_SPEED_MULTIPLIER * moveOffset.x; SFG_player.camera.position.y += SFG_PREVIEW_MODE_SPEED_MULTIPLIER * moveOffset.y; SFG_player.camera.height += SFG_PREVIEW_MODE_SPEED_MULTIPLIER * SFG_player.verticalSpeed; #else RCL_moveCameraWithCollision(&(SFG_player.camera),moveOffset, verticalOffset,SFG_floorHeightAt,SFG_ceilingHeightAt,1,1); SFG_player.previousVerticalSpeed = SFG_player.verticalSpeed; RCL_Unit limit = RCL_max(RCL_max(0,verticalOffset),SFG_player.verticalSpeed); SFG_player.verticalSpeed = RCL_min(limit,SFG_player.camera.height - previousHeight); /* ^ By "limit" we assure height increase caused by climbing a step doesn't add vertical velocity. */ #endif SFG_player.squarePosition[0] = SFG_player.camera.position.x / RCL_UNITS_PER_SQUARE; SFG_player.squarePosition[1] = SFG_player.camera.position.y / RCL_UNITS_PER_SQUARE; // handle door: if (SFG_currentLevel.doorRecordCount > 0) // has to be here { /* Check one door on whether a player is standing nearby. For performance reasons we only check one door and move to another in the next frame. */ SFG_DoorRecord *door = &(SFG_currentLevel.doorRecords[SFG_currentLevel.checkedDoorIndex]); door->state = (door->state & ~SFG_DOOR_UP_DOWN_MASK) | ( ((door->coords[0] >= (SFG_player.squarePosition[0] - 1)) && (door->coords[0] <= (SFG_player.squarePosition[0] + 1)) && (door->coords[1] >= (SFG_player.squarePosition[1] - 1)) && (door->coords[1] <= (SFG_player.squarePosition[1] + 1))) ? SFG_DOOR_UP_DOWN_MASK : 0x00 ); SFG_currentLevel.checkedDoorIndex++; if (SFG_currentLevel.checkedDoorIndex >= SFG_currentLevel.doorRecordCount) SFG_currentLevel.checkedDoorIndex = 0; for (uint32_t i = 0; i < SFG_currentLevel.doorRecordCount; ++i) { SFG_DoorRecord *door = &(SFG_currentLevel.doorRecords[i]); int8_t height = door->state & SFG_DOOR_VERTICAL_POSITION_MASK; height = (door->state & SFG_DOOR_UP_DOWN_MASK) ? RCL_min(0x1f,height + SFG_DOOR_INCREMENT_PER_FRAME) : RCL_max(0x00,height - SFG_DOOR_INCREMENT_PER_FRAME); door->state = (door->state & ~SFG_DOOR_VERTICAL_POSITION_MASK) | height; } } // handle items, in a similar manner to door: if (SFG_currentLevel.itemRecordCount > 0) // has to be here { SFG_ItemRecord item = SFG_currentLevel.itemRecords[SFG_currentLevel.checkedItemIndex]; item &= ~SFG_ITEM_RECORD_ACTIVE_MASK; SFG_LevelElement e = SFG_currentLevel.levelPointer->elements[item]; if ( (RCL_absVal(SFG_player.squarePosition[0] - e.coords[0]) <= SFG_LEVEL_ELEMENT_ACTIVE_DISTANCE) && (RCL_absVal(SFG_player.squarePosition[1] - e.coords[1]) <= SFG_LEVEL_ELEMENT_ACTIVE_DISTANCE) ) item |= SFG_ITEM_RECORD_ACTIVE_MASK; SFG_currentLevel.itemRecords[SFG_currentLevel.checkedItemIndex] = item; SFG_currentLevel.checkedItemIndex++; if (SFG_currentLevel.checkedItemIndex >= SFG_currentLevel.itemRecordCount) SFG_currentLevel.checkedItemIndex = 0; } } void SFG_clearScreen(uint8_t color) { for (uint16_t j = 0; j < SFG_GAME_RESOLUTION_Y; ++j) for (uint16_t i = 0; i < SFG_GAME_RESOLUTION_X; ++i) SFG_setGamePixel(i,j,color); } #define SFG_MAP_PIXEL_SIZE (SFG_GAME_RESOLUTION_Y / SFG_MAP_SIZE) #if SFG_MAP_PIXEL_SIZE == 0 #define SFG_MAP_SIZE 1 #endif /** Draws fullscreen map of the current level. */ void SFG_drawMap() { SFG_clearScreen(0); uint16_t maxJ = (SFG_MAP_PIXEL_SIZE * SFG_MAP_SIZE) < SFG_GAME_RESOLUTION_Y ? (SFG_MAP_SIZE) : (SFG_GAME_RESOLUTION_Y / SFG_MAP_PIXEL_SIZE); uint16_t maxI = (SFG_MAP_PIXEL_SIZE * SFG_MAP_SIZE) < SFG_GAME_RESOLUTION_X ? (SFG_MAP_SIZE) : (SFG_GAME_RESOLUTION_X / SFG_MAP_PIXEL_SIZE); uint16_t topLeftX = (SFG_GAME_RESOLUTION_X - (maxI * SFG_MAP_PIXEL_SIZE)) / 2; uint16_t topLeftY = (SFG_GAME_RESOLUTION_Y - (maxJ * SFG_MAP_PIXEL_SIZE)) / 2; uint16_t x; uint16_t y = topLeftY; for (int16_t j = maxJ - 1; j >= 0; --j) { x = topLeftX; for (uint16_t i = 0; i < maxI; ++i) { uint8_t properties; SFG_TileDefinition tile = SFG_getMapTile(SFG_currentLevel.levelPointer,i,j,&properties); uint8_t color = 94; // init with player color if (i != SFG_player.squarePosition[0] || j != SFG_player.squarePosition[1]) { if (properties == SFG_TILE_PROPERTY_ELEVATOR) color = 46; else if (properties == SFG_TILE_PROPERTY_SQUEEZER) color = 63; else { color = SFG_TILE_FLOOR_HEIGHT(tile) / 8 + 2; if (properties == SFG_TILE_PROPERTY_DOOR) color += 8; } } for (uint16_t k = 0; k < SFG_MAP_PIXEL_SIZE; ++k) for (uint16_t l = 0; l < SFG_MAP_PIXEL_SIZE; ++l) SFG_setGamePixel(x + l, y + k,color); x += SFG_MAP_PIXEL_SIZE; } y += SFG_MAP_PIXEL_SIZE; } } /** Draws text on screen using the bitmap font stored in assets. */ void SFG_drawText( const char *text, uint16_t x, uint16_t y, uint8_t size, uint8_t color) { if (size == 0) size = 1; uint16_t pos = 0; uint16_t currentX = x; uint16_t currentY = y; while (text[pos] != 0) { uint16_t character = SFG_font[SFG_charToFontIndex(text[pos])]; for (uint8_t i = 0; i < 4; ++i) { currentY = y; for (uint8_t j = 0; j < 4; ++j) { if (character & 0x8000) for (uint8_t k = 0; k < size; ++k) for (uint8_t l = 0; l < size; ++l) { uint16_t drawX = currentX + k; uint16_t drawY = currentY + l; if (drawX < SFG_GAME_RESOLUTION_X && drawY < SFG_GAME_RESOLUTION_Y) SFG_setGamePixel(drawX,drawY,color); } currentY += size; character = character << 1; } currentX += size; if (currentX >= SFG_GAME_RESOLUTION_X) break; } currentX += size; if (currentX >= SFG_GAME_RESOLUTION_X) break; pos++; } } void SFG_draw() { if (SFG_keyPressed(SFG_KEY_MAP)) { SFG_drawMap(); } else { for (uint16_t i = 0; i < SFG_GAME_RESOLUTION_X; ++i) SFG_zBuffer[i] = 255; #if SFG_HEADBOB_ENABLED RCL_Unit headBobOffset = (RCL_sinInt(SFG_player.headBobFrame) * SFG_HEADBOB_OFFSET) / RCL_UNITS_PER_SQUARE; // add head bob just for the rendering SFG_player.camera.height += headBobOffset; #endif RCL_renderComplex( SFG_player.camera, SFG_floorHeightAt, SFG_ceilingHeightAt, SFG_texturesAt, SFG_rayConstraints); // draw sprites: for (uint8_t i = 0; i < SFG_currentLevel.itemRecordCount; ++i) if (SFG_currentLevel.itemRecords[i] & SFG_ITEM_RECORD_ACTIVE_MASK) { RCL_Vector2D worldPosition; SFG_LevelElement e = SFG_currentLevel.levelPointer->elements[ SFG_currentLevel.itemRecords[i] & ~SFG_ITEM_RECORD_ACTIVE_MASK]; worldPosition.x = e.coords[0] * RCL_UNITS_PER_SQUARE + RCL_UNITS_PER_SQUARE / 2; worldPosition.y = e.coords[1] * RCL_UNITS_PER_SQUARE + RCL_UNITS_PER_SQUARE / 2; RCL_PixelInfo p = RCL_mapToScreen( worldPosition, SFG_floorHeightAt(e.coords[0],e.coords[1]) + RCL_UNITS_PER_SQUARE / 2, SFG_player.camera); if (p.depth > 0) SFG_drawScaledSprite(SFG_sprites[0],p.position.x,p.position.y, RCL_perspectiveScale(SFG_GAME_RESOLUTION_Y / 2,p.depth), p.depth / (RCL_UNITS_PER_SQUARE * 2),p.depth); } #if SFG_HEADBOB_ENABLED // substract head bob after rendering SFG_player.camera.height -= headBobOffset; #endif SFG_drawText("test text!",10,20,3,7); } } void SFG_mainLoopBody() { /* standard deterministic game loop, independed on actuall achieved FPS, each game logic (physics) frame is performed with the SFG_MS_PER_FRAME delta time. */ uint32_t timeNow = SFG_getTimeMs(); uint32_t timeNextFrame = SFG_lastFrameTimeMs + SFG_MS_PER_FRAME; SFG_frameTime = timeNow; if (timeNow >= timeNextFrame) { uint32_t timeSinceLastFrame = timeNow - SFG_lastFrameTimeMs; uint8_t steps = 0; // perform game logic (physics), for each frame while (timeSinceLastFrame >= SFG_MS_PER_FRAME) { SFG_gameStep(); timeSinceLastFrame -= SFG_MS_PER_FRAME; SFG_gameFrame++; steps++; } if (steps > 1) SFG_LOG("Failed to reach target FPS! Consider setting a lower value.") // render noly once SFG_draw(); SFG_lastFrameTimeMs = timeNow; } else { SFG_sleepMs((timeNextFrame - timeNow) / 2); // wait, relieve CPU } }