// ReC98 // ----- // PC-98 hardware constants not covered by master.lib #define PC98_H /// Spaces /// ------ /// These don't necessarily have to be relative to the top-left corner of the /// display. // Display-space widths, heights, and object-space coordinates typedef int pixel_t; typedef unsigned int upixel_t; // VRAM widths and object-space coordinates typedef int vram_byte_amount_t; typedef int vram_word_amount_t; typedef int vram_dword_amount_t; // TRAM widths and object-space coordinates typedef int tram_kanji_amount_t; typedef unsigned int utram_kanji_amount_t; /// ------ /// Coordinate systems /// ------------------ /// All of these are relative to the top-left corner of the final display. /// MODDERS: Remove the unsigned varieties. // Display-space coordinate, with [0; RES_X[ being the visible area. typedef int screen_x_t; typedef unsigned int uscreen_x_t; // Display-space coordinate, with [0; RES_Y[ being the visible area. Does not // care about 200- or 400-line graphics modes or vertical scrolling. typedef int screen_y_t; typedef unsigned int uscreen_y_t; // VRAM X coordinate, ranging from 0 to (RES_X / BYTE_DOTS). typedef int vram_x_t; // VRAM Y coordinate, ranging from 0 to either 400 or 200 depending on the // current graphics mode, and with an added vertical scrolling offset. typedef int vram_y_t; typedef unsigned int uvram_y_t; // Text RAM X coordinate, ranging from 0 to (RES_X / GLYPH_HALF_W). typedef int tram_x_t; typedef unsigned int utram_x_t; // Text RAM Y coordinate, ranging from 0 to (RES_Y / GLYPH_H). typedef int tram_y_t; typedef unsigned int utram_y_t; /// ------------------ /// Text /// ---- #define GAIJI_W 16 #define GAIJI_TRAM_W (GAIJI_W / 8) #define GLYPH_HALF_W 8 #define GLYPH_FULL_W 16 #define GLYPH_H 16 #define shiftjis_w(literal) \ ((sizeof(literal) - 1) * GLYPH_HALF_W) /// ---- /// Graphics /// -------- #define BYTE_DOTS 8 #define RES_X 640 #define RES_Y 400 #define ROW_SIZE (RES_X / BYTE_DOTS) #define PLANE_SIZE (ROW_SIZE * RES_Y) #define PLANE_COUNT 4 typedef bool page_t; #define COLOR_COUNT 16 #define COMPONENT_COUNT 3 // The 16-color mode supports 4 bits per RGB component, for a total of // 4,096 colors typedef int8_t uint4_t; #ifdef __cplusplus template union RGB { struct { ComponentType r, g, b; } c; ComponentType v[COMPONENT_COUNT]; // Yes, we actually need this function in certain cases where code // generation calls for a 0 in the ComponentType. static ComponentType min() { return 0; } static ComponentType max() { return (Range - 1); } void set(ComponentType r, ComponentType g, ComponentType b) { this->c.r = r; this->c.g = g; this->c.b = b; } }; template struct Palette { RGBType colors[COLOR_COUNT]; static int range() { return RGBType::Range; } RGBType& operator [](int col) { return colors[col]; } const RGBType& operator [](int col) const { return colors[col]; } }; typedef RGB RGB4; typedef Palette Palette4; #define palette_foreach(tmp_col, tmp_comp, func) { \ for(tmp_col = 0; tmp_col < COLOR_COUNT; tmp_col++) { \ for(tmp_comp = 0; tmp_comp < COMPONENT_COUNT; tmp_comp++) { \ func \ } \ } \ } // Sets all components of all colors to the given grayscale [value]. #define palette_set_grayscale(dst, value, tmp_col, tmp_comp) \ palette_foreach(tmp_col, tmp_comp, { \ dst[tmp_col].v[tmp_comp] = value; \ }) #define palette_copy(dst, src, tmp_col, tmp_comp) \ palette_foreach(tmp_col, tmp_comp, { \ dst[col].v[comp] = src[col].v[comp]; \ }) #endif /// -------- /// Memory segments /// --------------- #define SEG_TRAM_JIS 0xA000 #define SEG_TRAM_ATRB 0xA200 #define SEG_PLANE_B 0xA800 #define SEG_PLANE_R 0xB000 #define SEG_PLANE_G 0xB800 #define SEG_PLANE_E 0xE000 // Segment distance between B↔R↔G #define SEG_PLANE_DIST_BRG 0x800 // Segment distance between G↔E #define SEG_PLANE_DIST_E 0x2800 /// ---------------