ReC98/th01/hardware/graph.cpp

731 lines
17 KiB
C++

#pragma option -Z
extern "C" {
#include <dos.h>
#include <mbctype.h>
#include <mbstring.h>
#include "ReC98.h"
#include "th01/hardware/egc.h"
#include "th01/hardware/vsync.h"
#include "th01/hardware/graph.h"
#include "th01/hardware/palette.hpp"
/// VRAM plane "structures"
/// -----------------------
#define Planes_declare(var) \
planar8_t *var##_B = reinterpret_cast<planar8_t *>(MK_FP(SEG_PLANE_B, 0)); \
planar8_t *var##_R = reinterpret_cast<planar8_t *>(MK_FP(SEG_PLANE_R, 0)); \
planar8_t *var##_G = reinterpret_cast<planar8_t *>(MK_FP(SEG_PLANE_G, 0)); \
planar8_t *var##_E = reinterpret_cast<planar8_t *>(MK_FP(SEG_PLANE_E, 0));
#define Planes_next_row(var) \
var##_B += ROW_SIZE; \
var##_R += ROW_SIZE; \
var##_G += ROW_SIZE; \
var##_E += ROW_SIZE;
#define Planes_offset(var, x, y) \
var##_B += (x / 8) + (y * ROW_SIZE); \
var##_R += (x / 8) + (y * ROW_SIZE); \
var##_G += (x / 8) + (y * ROW_SIZE); \
var##_E += (x / 8) + (y * ROW_SIZE);
#define PlanarRow_declare(var) \
planar8_t var##_B[ROW_SIZE]; \
planar8_t var##_R[ROW_SIZE]; \
planar8_t var##_G[ROW_SIZE]; \
planar8_t var##_E[ROW_SIZE]; \
#define PlanarRow_blit(dst, src, bytes) \
memcpy(dst##_B, src##_B, bytes); \
memcpy(dst##_R, src##_R, bytes); \
memcpy(dst##_G, src##_G, bytes); \
memcpy(dst##_E, src##_E, bytes);
/// -----------------------
/// Clipping
/// --------
#define fix_order(low, high) \
if(low > high) { \
order_tmp = low; \
low = high; \
high = order_tmp; \
}
#define clip_min(low, high, minimum) \
if(low < minimum) { \
if(high < minimum) { \
return; \
} \
low = minimum; \
}
#define clip_max(low, high, maximum) \
if(high > maximum) { \
if(low > maximum) { \
return; \
} \
high = maximum; \
}
#define clip_x(left, right) \
clip_min(left, right, 0); \
clip_max(left, right, (RES_X - 1));
#define clip_y(top, bottom) \
clip_min(top, bottom, 0); \
clip_max(top, bottom, (RES_Y - 1));
/// --------
/// Temporary translation unit mismatch workarounds
/// -----------------------------------------------
#define GRCG_SETCOLOR_RMW(col) __asm { \
push col; \
push cs; \
call near ptr grcg_setcolor_rmw; \
pop cx; \
}
#define GRCG_OFF() __asm { \
push cs; \
call near ptr grcg_off_func; \
}
#define GRAPH_ACCESSPAGE_FUNC(page, stack_clear_size) __asm { \
push page; \
push cs; \
call near ptr graph_accesspage_func; \
} \
_SP += stack_clear_size;
/// -----------------------------------------------
/// Pages
/// -----
extern page_t page_back;
/// -----
/// Points
/// ------
#define VRAM_SBYTE(plane, offset) \
*reinterpret_cast<splanar8_t *>(MK_FP(SEG_PLANE_##plane, offset))
void z_grcg_pset(int x, int y, int col)
{
GRCG_SETCOLOR_RMW(col);
VRAM_SBYTE(B, ((y * ROW_SIZE) + (x >> 3))) = (0x80 >> (x & 7));
GRCG_OFF();
}
int z_col_at(int x, int y)
{
int ret;
int vram_offset = ((y * ROW_SIZE) + (x >> 3));
splanar16_t mask = (0x80 >> (x & 7));
#define test(plane, vram_offset, mask, bit) \
if(VRAM_SBYTE(plane, vram_offset) & mask) { \
ret |= bit; \
}
ret = 0;
test(B, vram_offset, mask, 1);
test(R, vram_offset, mask, 2);
test(G, vram_offset, mask, 4);
test(E, vram_offset, mask, 8);
return ret;
#undef text
}
/// ------
/// Restorable line drawing
/// -----------------------
// Never read from, so it's supposedly only there for debugging purposes?
extern Point graph_r_last_line_end;
// `true` copies the pixels to be drawn from the same position on page 1, thus
// restoring them with the background image. `false` (the default) draws them
// regularly the given [col].
extern bool graph_r_restore_from_1;
// Not used for purely horizontal lines.
extern planar16_t graph_r_pattern;
void graph_r_hline(int left, int right, int y, int col)
{
int full_bytes_to_put;
int order_tmp;
planar8_t left_pixels;
planar8_t right_pixels;
planar8_t *vram_row;
fix_order(left, right);
clip_x(left, right);
graph_r_last_line_end.x = right;
graph_r_last_line_end.y = y;
vram_row = (planar8_t *)(MK_FP(GRAM_400, (y * ROW_SIZE) + (left / 8)));
full_bytes_to_put = (right / 8) - (left / 8);
left_pixels = 0xFF >> (left & 7);
right_pixels = 0xFF << (7 - (right & 7));
if(!graph_r_restore_from_1) {
GRCG_SETCOLOR_RMW(col);
}
if(graph_r_restore_from_1) {
egc_copy_rect_1_to_0(left, y, RES_X - left, 1);
} else {
if(full_bytes_to_put == 0) {
vram_row[0] = (left_pixels & right_pixels);
} else {
vram_row[0] = left_pixels;
for(register int x = 1; x < full_bytes_to_put; x++) {
vram_row[x] = 0xFF;
}
vram_row[full_bytes_to_put] = right_pixels;
}
}
if(!graph_r_restore_from_1) {
GRCG_OFF();
}
}
void graph_r_vline(int x, int top, int bottom, int col)
{
int y;
int order_tmp;
planar16_t pattern;
int vram_row_offset;
fix_order(top, bottom);
clip_y(top, bottom);
graph_r_last_line_end.x = x;
graph_r_last_line_end.y = bottom;
if(graph_r_restore_from_1) {
egc_copy_rect_1_to_0(x, top, sizeof(pattern) * 8, bottom - top);
return;
}
vram_row_offset = VRAM_OFFSET(x, top);
pattern = graph_r_pattern >> (x & 7);
pattern |= graph_r_pattern << (16 - (x & 7));
GRCG_SETCOLOR_RMW(col);
for(y = top; y <= bottom; y++) {
VRAM_PUT(B, vram_row_offset, pattern, 16);
vram_row_offset += ROW_SIZE;
}
GRCG_OFF();
}
void graph_r_line_from_1(int left, int top, int right, int bottom)
{
graph_r_restore_from_1 = true;
graph_r_line(left, top, right, bottom, 7);
graph_r_restore_from_1 = false;
}
void graph_r_line_patterned(
int left, int top, int right, int bottom, int col, planar16_t pattern
)
{
graph_r_pattern = pattern;
graph_r_line(left, top, right, bottom, col);
graph_r_pattern = 0x80;
}
void graph_r_line(int left, int top, int right, int bottom, int col)
{
register int vram_offset;
int i;
int x_cur, y_cur;
int w, h;
int error;
int y_direction;
int order_tmp;
int x_vram, y_vram;
planar16_t pixels;
vram_planar_32_pixels_t page1;
#define slope_x ((bottom - top) / (right - left))
#define slope_y ((right - left) / (bottom - top))
#define lerp(m, x) static_cast<int>(m * static_cast<float>(x))
#define clip_lerp_min(low, high, lerp_point, slope, minimum) \
if(low < minimum) { \
if(high < minimum) { \
return; \
} \
lerp_point += lerp(slope, (minimum - low)); \
low = minimum; \
}
#define clip_lerp_max(low, high, lerp_point, slope, maximum) \
if(high > maximum) { \
if(low > maximum) { \
return; \
} \
lerp_point -= lerp(slope, (high - maximum)); \
high = maximum; \
}
#define restore_at(bit_count) \
GRAPH_ACCESSPAGE_FUNC(1, 0); VRAM_SNAP_4(page1, vram_offset, 32); \
GRAPH_ACCESSPAGE_FUNC(0, 4); VRAM_PUT_4(vram_offset, page1, 32);
#define plot_loop(\
step_var, step_len, step_increment, \
plotted_var, plotted_len, plotted_increment \
) \
error = (step_len >> 1); \
for(i = 0; i <= step_len; i++) { \
/* Advanced past the VRAM cursor? */ \
if((x_cur >> 3) != x_vram || (y_vram != y_cur)) { \
vram_offset = (y_vram * ROW_SIZE) + x_vram; \
if(!graph_r_restore_from_1) { \
VRAM_PUT(B, vram_offset, pixels, 16); \
pixels = 0; \
} else { \
vram_offset--; \
restore_at(vram_offset); \
} \
y_vram = y_cur; \
x_vram = (x_cur >> 3); \
} \
pixels |= (graph_r_pattern >> (x_cur & 7)); \
pixels |= (graph_r_pattern << (16 - (x_cur & 7))); \
error -= plotted_len; \
step_var += step_increment; \
if(error < 0) { \
error += step_len; \
plotted_var += plotted_increment; \
} \
} \
if(graph_r_restore_from_1) { \
goto restore_last; \
} \
goto end;
if(!graph_r_restore_from_1 && (left == right)) {
graph_r_vline(left, top, bottom, col);
return;
}
if(!graph_r_restore_from_1 && (top == bottom)) {
graph_r_hline(left, right, top, col);
return;
}
if(left > right) {
order_tmp = left;
left = right;
right = order_tmp;
order_tmp = top;
top = bottom;
bottom = order_tmp;
}
clip_lerp_min(left, right, top, slope_x, 0);
clip_lerp_max(left, right, bottom, slope_x, (RES_X - 1));
clip_lerp_min(top, bottom, left, slope_y, 0);
clip_lerp_max(top, bottom, right, slope_y, (RES_Y - 1));
if(bottom < 0) {
right += lerp(slope_y, 0 - bottom);
bottom = 0;
}
if(top > (RES_Y - 1)) {
left -= lerp(slope_y, top - (RES_Y - 1));
top = (RES_Y - 1);
}
graph_r_last_line_end.x = right;
graph_r_last_line_end.y = bottom;
x_cur = left;
y_cur = top;
y_direction = (top < bottom) ? 1 : -1;
w = right - left;
h = (bottom - top) * y_direction;
pixels = 0;
x_vram = (x_cur >> 3);
y_vram = y_cur;
if(!graph_r_restore_from_1) {
GRCG_SETCOLOR_RMW(col);
}
if(w > h) {
plot_loop(x_cur, w, 1, y_cur, h, y_direction);
} else {
plot_loop(y_cur, h, y_direction, x_cur, w, 1);
}
restore_last:
vram_offset = VRAM_OFFSET(x_cur, y_cur) - 1;
restore_at(vram_offset);
end:
if(!graph_r_restore_from_1) {
GRCG_OFF();
}
#undef plot_loop
#undef restore_at
#undef clip_lerp_min
#undef clip_lerp_max
#undef slope
}
/// -----------------------
void z_grcg_boxfill(int left, int top, int right, int bottom, int col)
{
int x;
int y;
int full_bytes_to_put;
int order_tmp;
planar8_t left_pixels;
planar8_t right_pixels;
planar8_t *vram_row;
fix_order(left, right);
fix_order(top, bottom);
clip_x(left, right);
clip_y(top, bottom);
GRCG_SETCOLOR_RMW(col);
vram_row = (planar8_t *)(MK_FP(GRAM_400, (top * ROW_SIZE) + (left >> 3)));
for(y = top; y <= bottom; y++) {
full_bytes_to_put = (right >> 3) - (left >> 3);
left_pixels = 0xFF >> (left & 7);
right_pixels = 0xFF << (7 - (right & 7));
if(full_bytes_to_put == 0) {
vram_row[0] = (left_pixels & right_pixels);
} else {
vram_row[0] = left_pixels;
for(x = 1; x < full_bytes_to_put; x++) {
vram_row[x] = 0xFF;
}
vram_row[full_bytes_to_put] = right_pixels;
}
vram_row += ROW_SIZE;
}
GRCG_OFF();
}
void graph_r_box(int left, int top, int right, int bottom, int col)
{
graph_r_hline(left, right, top, col);
graph_r_vline(left, top, bottom, col);
graph_r_vline(right, top, bottom, col);
graph_r_hline(left, right, bottom, col);
}
int text_extent_fx(int fx, const unsigned char *str)
{
register int ret = 0;
register int spacing = (fx / 0x40) % 8;
while(*str) {
if(_ismbblead(str[0])) {
uint16_t codepoint = ((char)str[0] << 8) + str[0];
str++;
str++;
if(codepoint < 0x8540) {
ret += GLYPH_FULL_W;
} else if(codepoint > 0x869E) {
ret += GLYPH_FULL_W;
} else {
ret += GLYPH_HALF_W;
}
} else {
ret += GLYPH_HALF_W;
str++;
}
ret += spacing;
}
return ret - spacing;
}
#include "th01/hardware/grppsafx.c"
void graph_putsa_fx(int left, int top, int fx, const unsigned char *str)
{
uint16_t codepoint;
planar16_t glyph_row;
unsigned char far *vram;
int fullwidth;
int first_bit;
int weight = (fx / 0x10) % 4;
int spacing = (fx / 0x40) % 8;
int clear_bg = (fx & FX_CLEAR_BG);
int underline = (fx & FX_UNDERLINE);
int reverse = (fx & FX_REVERSE);
int w;
int line;
planar16_t glyph[GLYPH_H];
planar16_t glyph_row_tmp;
if(clear_bg) {
w = text_extent_fx(fx, str);
if(underline) {
z_grcg_boxfill(left, top, (left + w - 1), (top + GLYPH_H + 1), 0);
graph_r_hline(left, (left + w - 1), (top + GLYPH_H + 1), 7);
} else {
z_grcg_boxfill(left, top, (left + w - 1), (top + GLYPH_H - 1), 0);
}
} else if(underline) {
w = text_extent_fx(fx, str);
graph_r_hline(left, (left + w - 1), (top + GLYPH_H + 1), 7);
}
GRCG_SETCOLOR_RMW(fx);
OUTB(0x68, 0xB); // CG ROM dot access
while(str[0]) {
set_vram_ptr(vram, first_bit, left, top);
get_glyph(glyph, codepoint, fullwidth, str, left, line);
for(line = 0; line < GLYPH_H; line++) {
apply_weight(glyph_row, glyph[line], glyph_row_tmp, weight);
if(reverse) {
if(fullwidth) {
glyph_row ^= 0xFFFF;
} else {
glyph_row ^= 0xFF00;
}
}
put_row_and_advance(vram, glyph_row, first_bit);
}
advance_left(left, fullwidth, spacing);
}
OUTB(0x68, 0xA); // CG ROM code access
GRCG_OFF();
}
void graph_copy_byterect_back_to_front(
int left, int top, int right, int bottom
)
{
int w = (right - left) / 8;
int h = (bottom - top);
Planes_declare(p);
page_t page_front = page_back ^ 1;
int row;
PlanarRow_declare(tmp);
Planes_offset(p, left, top);
for(row = 0; row < h; row++) {
PlanarRow_blit(tmp, p, w);
graph_accesspage(page_front);
PlanarRow_blit(p, tmp, w);
graph_accesspage(page_back);
Planes_next_row(p);
}
}
void graph_move_byterect_interpage(
int src_left, int src_top, int src_right, int src_bottom,
int dst_left, int dst_top,
page_t src, page_t dst
)
{
int w = (src_right - src_left) / 8;
int h = (src_bottom - src_top);
Planes_declare(src);
Planes_declare(dst);
int row;
PlanarRow_declare(tmp);
Planes_offset(src, src_left, src_top);
Planes_offset(dst, dst_left, dst_top);
for(row = 0; row < h; row++) {
PlanarRow_blit(tmp, src, w);
graph_accesspage(dst);
PlanarRow_blit(dst, tmp, w);
graph_accesspage(src);
Planes_next_row(src);
Planes_next_row(dst);
}
graph_accesspage(page_back);
}
void z_palette_fade_from(
uint4_t from_r, uint4_t from_g, uint4_t from_b,
int keep[COLOR_COUNT],
unsigned int step_ms
)
{
RGB4 fadepal[COLOR_COUNT];
int i;
int col;
int comp;
memset(&fadepal, 0x0, sizeof(fadepal));
for(i = 0; i < COLOR_COUNT; i++) {
if(!keep[i]) {
fadepal[i].c.r = from_r;
fadepal[i].c.g = from_g;
fadepal[i].c.b = from_b;
} else {
fadepal[i].c.r = z_Palettes.colors[i].c.r;
fadepal[i].c.g = z_Palettes.colors[i].c.g;
fadepal[i].c.b = z_Palettes.colors[i].c.b;
}
}
for(i = 0; i < 16; i++) {
z_vsync_wait();
for(col = 0; col < COLOR_COUNT; col++) {
for(comp = 0; comp < sizeof(RGB4); comp++) {
if(fadepal[col].v[comp] != z_Palettes.colors[col].v[comp]) {
fadepal[col].v[comp] +=
(fadepal[col].v[comp] < z_Palettes.colors[col].v[comp])
? 1
: -1;
}
}
/* TODO: Replace with the decompiled call
* z_palette_show_single_col(col, fadepal[col]);
* once that function is part of this translation unit */
__asm {
#define push_comp(comp) \
mov bx, col; \
db 0x6B, 0xDB, 0x03; /* IMUL BX, 3, which Turbo C++ can't into? */ \
lea ax, fadepal[comp]; \
db 0x03, 0xD8; /* Turbo C++'s preferred opcode for ADD BX, AX */ \
mov al, ss:[bx]; \
cbw; \
push ax;
push_comp(2)
push_comp(1)
push_comp(0)
push col
push cs
call near ptr z_palette_show_single
add sp, 8
}
}
delay(step_ms);
}
}
// Resident palette
// ----------------
#define RESPAL_ID "pal98 grb"
struct hack { char x[sizeof(RESPAL_ID)]; }; // XXX
extern const hack PAL98_GRB;
#pragma option -a1
// MASTER.MAN suggests that GBR ordering is some sort of standard on PC-98.
// It does match the order of the hardware's palette register ports, after
// all. (0AAh = green, 0ACh = red, 0AEh = blue)
struct grb_t {
uint4_t g, r, b;
};
struct respal_t {
char id[sizeof(RESPAL_ID)];
unsigned char tone;
int8_t padding[5];
grb_t pal[COLOR_COUNT];
};
// ----------------
// Memory Control Block
// Adapted from FreeDOS' kernel/hdr/mcb.h
// --------------------
#define MCB_NORMAL 0x4d
#define MCB_LAST 0x5a
struct mcb_t {
uint8_t m_type; // mcb type - chain or end
uint16_t __seg* m_psp; // owner id via psp segment
uint16_t m_size; // size of segment in paragraphs
uint8_t m_fill[3];
uint8_t m_name[8];
};
#pragma option -a.
respal_t __seg* z_respal_exist(void)
{
union REGS regs;
struct SREGS sregs;
const hack ID = PAL98_GRB;
seg_t mcb;
int i;
#define MCB reinterpret_cast<mcb_t __seg *>(mcb) /* For easy derefencing */
#define MCB_PARAS (sizeof(mcb_t) / 16) /* For segment pointer arithmetic */
// "Get list of lists"
segread(&sregs);
regs.h.ah = 0x52;
intdosx(&regs, &regs, &sregs);
mcb = *reinterpret_cast<seg_t *>(MK_FP(sregs.es, regs.w.bx - 2));
while(1) {
if(MCB->m_psp != 0) {
for(i = 0; i < sizeof(ID); i++) {
if(reinterpret_cast<respal_t *>(MCB + 1)->id[i] != ID.x[i]) {
break;
}
}
if(i == sizeof(ID)) {
return reinterpret_cast<respal_t __seg *>(mcb + MCB_PARAS);
}
}
if(MCB->m_type != MCB_NORMAL) {
return 0;
}
mcb += MCB_PARAS + MCB->m_size;
};
#undef MCB_PARAS
#undef MCB
}
int z_respal_get_show(void)
{
int i;
respal_t __seg *respal_seg = z_respal_exist();
if(respal_seg) {
grb_t *respal = respal_seg->pal;
for(i = 0; i < COLOR_COUNT; i++) {
/* TODO: Replace with the decompiled call
* z_palette_set_show(i, respal->r, respal->g, respal->b);
* once that function is part of this translation unit */
__asm {
les bx, respal
mov al, es:[bx+2]
cbw
push ax
mov al, es:[bx+0]
cbw
push ax
mov al, es:[bx+1]
cbw
push ax
// Spelling out PUSH SI causes Turbo C++ to interpret SI as
// reserved, and it then moves [i] to DI rather than SI
db 0x56
push cs
call near ptr z_palette_set_show
add sp, 8
}
respal++;
}
return 0;
}
return 1;
}
int z_respal_set(void)
{
int i;
respal_t __seg *respal_seg = z_respal_exist();
if(respal_seg) {
grb_t *respal = respal_seg->pal;
for(i = 0; i < COLOR_COUNT; i++) {
respal->g = z_Palettes.colors[i].c.g;
respal->r = z_Palettes.colors[i].c.r;
respal->b = z_Palettes.colors[i].c.b;
respal++;
}
return 0;
}
return 1;
}
}