frodo-wii/Src/VIC.cpp

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2009-01-13 19:46:42 +01:00
/*
* VIC.cpp - 6569R5 emulation (line based)
*
* Frodo (C) 1994-1997,2002-2005 Christian Bauer
*
* This program is free software; you can redistribute it and/or modify
* it under the terms of the GNU General Public License as published by
* the Free Software Foundation; either version 2 of the License, or
* (at your option) any later version.
*
* This program is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with this program; if not, write to the Free Software
* Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
*/
/*
* Notes:
* ------
*
* - The EmulateLine() function is called for every emulated
* raster line. It computes one pixel row of the graphics
* according to the current VIC register settings and returns
* the number of cycles available for the CPU in that line.
* - The graphics are output into an 8 bit chunky bitmap
* - The sprite-graphics priority handling and collision
* detection is done in a bit-oriented way with masks.
* The foreground/background pixel mask for the graphics
* is stored in the fore_mask_buf[] array. Multicolor
* sprites are converted from their original chunky format
* to a bitplane representation (two bit masks) for easier
* handling of priorities and collisions.
* - The sprite-sprite priority handling and collision
* detection is done in with the byte array spr_coll_buf[],
* that is used to keep track of which sprites are already
* visible at certain X positions.
*
* Incompatibilities:
* ------------------
*
* - Raster effects that are achieved by modifying VIC registers
* in the middle of a raster line cannot be emulated
* - Sprite collisions are only detected within the visible
* screen area (excluding borders)
* - Sprites are only drawn if they completely fit within the
* left/right limits of the chunky bitmap
* - The Char ROM is not visible in the bitmap displays at
* addresses $0000 and $8000
* - The IRQ is cleared on every write access to the flag
* register. This is a hack for the RMW instructions of the
* 6510 that first write back the original value.
*/
#include "sysdeps.h"
#include "VIC.h"
#include "C64.h"
#include "CPUC64.h"
#include "Display.h"
#include "Prefs.h"
// Test alignment on run-time for processors that can't access unaligned:
#ifdef __riscos__
#define ALIGNMENT_CHECK
#endif
// First and last displayed line
const unsigned FIRST_DISP_LINE = 0x10;
const unsigned LAST_DISP_LINE = 0x11f;
// First and last possible line for Bad Lines
const unsigned FIRST_DMA_LINE = 0x30;
const unsigned LAST_DMA_LINE = 0xf7;
// Display window coordinates
const int ROW25_YSTART = 0x33;
const int ROW25_YSTOP = 0xfb;
const int ROW24_YSTART = 0x37;
const int ROW24_YSTOP = 0xf7;
#if defined(SMALL_DISPLAY)
/* This does not work yet, the sprite code doesn't know about it. */
const int COL40_XSTART = 0x14;
const int COL40_XSTOP = 0x154;
const int COL38_XSTART = 0x1B;
const int COL38_XSTOP = 0x14B;
#else
const int COL40_XSTART = 0x20;
const int COL40_XSTOP = 0x160;
const int COL38_XSTART = 0x27;
const int COL38_XSTOP = 0x157;
#endif
// Tables for sprite X expansion
uint16 ExpTable[256] = {
0x0000, 0x0003, 0x000C, 0x000F, 0x0030, 0x0033, 0x003C, 0x003F,
0x00C0, 0x00C3, 0x00CC, 0x00CF, 0x00F0, 0x00F3, 0x00FC, 0x00FF,
0x0300, 0x0303, 0x030C, 0x030F, 0x0330, 0x0333, 0x033C, 0x033F,
0x03C0, 0x03C3, 0x03CC, 0x03CF, 0x03F0, 0x03F3, 0x03FC, 0x03FF,
0x0C00, 0x0C03, 0x0C0C, 0x0C0F, 0x0C30, 0x0C33, 0x0C3C, 0x0C3F,
0x0CC0, 0x0CC3, 0x0CCC, 0x0CCF, 0x0CF0, 0x0CF3, 0x0CFC, 0x0CFF,
0x0F00, 0x0F03, 0x0F0C, 0x0F0F, 0x0F30, 0x0F33, 0x0F3C, 0x0F3F,
0x0FC0, 0x0FC3, 0x0FCC, 0x0FCF, 0x0FF0, 0x0FF3, 0x0FFC, 0x0FFF,
0x3000, 0x3003, 0x300C, 0x300F, 0x3030, 0x3033, 0x303C, 0x303F,
0x30C0, 0x30C3, 0x30CC, 0x30CF, 0x30F0, 0x30F3, 0x30FC, 0x30FF,
0x3300, 0x3303, 0x330C, 0x330F, 0x3330, 0x3333, 0x333C, 0x333F,
0x33C0, 0x33C3, 0x33CC, 0x33CF, 0x33F0, 0x33F3, 0x33FC, 0x33FF,
0x3C00, 0x3C03, 0x3C0C, 0x3C0F, 0x3C30, 0x3C33, 0x3C3C, 0x3C3F,
0x3CC0, 0x3CC3, 0x3CCC, 0x3CCF, 0x3CF0, 0x3CF3, 0x3CFC, 0x3CFF,
0x3F00, 0x3F03, 0x3F0C, 0x3F0F, 0x3F30, 0x3F33, 0x3F3C, 0x3F3F,
0x3FC0, 0x3FC3, 0x3FCC, 0x3FCF, 0x3FF0, 0x3FF3, 0x3FFC, 0x3FFF,
0xC000, 0xC003, 0xC00C, 0xC00F, 0xC030, 0xC033, 0xC03C, 0xC03F,
0xC0C0, 0xC0C3, 0xC0CC, 0xC0CF, 0xC0F0, 0xC0F3, 0xC0FC, 0xC0FF,
0xC300, 0xC303, 0xC30C, 0xC30F, 0xC330, 0xC333, 0xC33C, 0xC33F,
0xC3C0, 0xC3C3, 0xC3CC, 0xC3CF, 0xC3F0, 0xC3F3, 0xC3FC, 0xC3FF,
0xCC00, 0xCC03, 0xCC0C, 0xCC0F, 0xCC30, 0xCC33, 0xCC3C, 0xCC3F,
0xCCC0, 0xCCC3, 0xCCCC, 0xCCCF, 0xCCF0, 0xCCF3, 0xCCFC, 0xCCFF,
0xCF00, 0xCF03, 0xCF0C, 0xCF0F, 0xCF30, 0xCF33, 0xCF3C, 0xCF3F,
0xCFC0, 0xCFC3, 0xCFCC, 0xCFCF, 0xCFF0, 0xCFF3, 0xCFFC, 0xCFFF,
0xF000, 0xF003, 0xF00C, 0xF00F, 0xF030, 0xF033, 0xF03C, 0xF03F,
0xF0C0, 0xF0C3, 0xF0CC, 0xF0CF, 0xF0F0, 0xF0F3, 0xF0FC, 0xF0FF,
0xF300, 0xF303, 0xF30C, 0xF30F, 0xF330, 0xF333, 0xF33C, 0xF33F,
0xF3C0, 0xF3C3, 0xF3CC, 0xF3CF, 0xF3F0, 0xF3F3, 0xF3FC, 0xF3FF,
0xFC00, 0xFC03, 0xFC0C, 0xFC0F, 0xFC30, 0xFC33, 0xFC3C, 0xFC3F,
0xFCC0, 0xFCC3, 0xFCCC, 0xFCCF, 0xFCF0, 0xFCF3, 0xFCFC, 0xFCFF,
0xFF00, 0xFF03, 0xFF0C, 0xFF0F, 0xFF30, 0xFF33, 0xFF3C, 0xFF3F,
0xFFC0, 0xFFC3, 0xFFCC, 0xFFCF, 0xFFF0, 0xFFF3, 0xFFFC, 0xFFFF
};
uint16 MultiExpTable[256] = {
0x0000, 0x0005, 0x000A, 0x000F, 0x0050, 0x0055, 0x005A, 0x005F,
0x00A0, 0x00A5, 0x00AA, 0x00AF, 0x00F0, 0x00F5, 0x00FA, 0x00FF,
0x0500, 0x0505, 0x050A, 0x050F, 0x0550, 0x0555, 0x055A, 0x055F,
0x05A0, 0x05A5, 0x05AA, 0x05AF, 0x05F0, 0x05F5, 0x05FA, 0x05FF,
0x0A00, 0x0A05, 0x0A0A, 0x0A0F, 0x0A50, 0x0A55, 0x0A5A, 0x0A5F,
0x0AA0, 0x0AA5, 0x0AAA, 0x0AAF, 0x0AF0, 0x0AF5, 0x0AFA, 0x0AFF,
0x0F00, 0x0F05, 0x0F0A, 0x0F0F, 0x0F50, 0x0F55, 0x0F5A, 0x0F5F,
0x0FA0, 0x0FA5, 0x0FAA, 0x0FAF, 0x0FF0, 0x0FF5, 0x0FFA, 0x0FFF,
0x5000, 0x5005, 0x500A, 0x500F, 0x5050, 0x5055, 0x505A, 0x505F,
0x50A0, 0x50A5, 0x50AA, 0x50AF, 0x50F0, 0x50F5, 0x50FA, 0x50FF,
0x5500, 0x5505, 0x550A, 0x550F, 0x5550, 0x5555, 0x555A, 0x555F,
0x55A0, 0x55A5, 0x55AA, 0x55AF, 0x55F0, 0x55F5, 0x55FA, 0x55FF,
0x5A00, 0x5A05, 0x5A0A, 0x5A0F, 0x5A50, 0x5A55, 0x5A5A, 0x5A5F,
0x5AA0, 0x5AA5, 0x5AAA, 0x5AAF, 0x5AF0, 0x5AF5, 0x5AFA, 0x5AFF,
0x5F00, 0x5F05, 0x5F0A, 0x5F0F, 0x5F50, 0x5F55, 0x5F5A, 0x5F5F,
0x5FA0, 0x5FA5, 0x5FAA, 0x5FAF, 0x5FF0, 0x5FF5, 0x5FFA, 0x5FFF,
0xA000, 0xA005, 0xA00A, 0xA00F, 0xA050, 0xA055, 0xA05A, 0xA05F,
0xA0A0, 0xA0A5, 0xA0AA, 0xA0AF, 0xA0F0, 0xA0F5, 0xA0FA, 0xA0FF,
0xA500, 0xA505, 0xA50A, 0xA50F, 0xA550, 0xA555, 0xA55A, 0xA55F,
0xA5A0, 0xA5A5, 0xA5AA, 0xA5AF, 0xA5F0, 0xA5F5, 0xA5FA, 0xA5FF,
0xAA00, 0xAA05, 0xAA0A, 0xAA0F, 0xAA50, 0xAA55, 0xAA5A, 0xAA5F,
0xAAA0, 0xAAA5, 0xAAAA, 0xAAAF, 0xAAF0, 0xAAF5, 0xAAFA, 0xAAFF,
0xAF00, 0xAF05, 0xAF0A, 0xAF0F, 0xAF50, 0xAF55, 0xAF5A, 0xAF5F,
0xAFA0, 0xAFA5, 0xAFAA, 0xAFAF, 0xAFF0, 0xAFF5, 0xAFFA, 0xAFFF,
0xF000, 0xF005, 0xF00A, 0xF00F, 0xF050, 0xF055, 0xF05A, 0xF05F,
0xF0A0, 0xF0A5, 0xF0AA, 0xF0AF, 0xF0F0, 0xF0F5, 0xF0FA, 0xF0FF,
0xF500, 0xF505, 0xF50A, 0xF50F, 0xF550, 0xF555, 0xF55A, 0xF55F,
0xF5A0, 0xF5A5, 0xF5AA, 0xF5AF, 0xF5F0, 0xF5F5, 0xF5FA, 0xF5FF,
0xFA00, 0xFA05, 0xFA0A, 0xFA0F, 0xFA50, 0xFA55, 0xFA5A, 0xFA5F,
0xFAA0, 0xFAA5, 0xFAAA, 0xFAAF, 0xFAF0, 0xFAF5, 0xFAFA, 0xFAFF,
0xFF00, 0xFF05, 0xFF0A, 0xFF0F, 0xFF50, 0xFF55, 0xFF5A, 0xFF5F,
0xFFA0, 0xFFA5, 0xFFAA, 0xFFAF, 0xFFF0, 0xFFF5, 0xFFFA, 0xFFFF
};
#ifdef __POWERPC__
static union {
struct {
uint8 a,b,c,d,e,f,g,h;
} a;
double b;
} TextColorTable[16][16][256];
#else
static union {
struct {
uint8 a,b,c,d;
} a;
uint32 b;
} TextColorTable[16][16][256][2];
#endif
#ifdef GLOBAL_VARS
static uint16 mc_color_lookup[4];
#ifndef CAN_ACCESS_UNALIGNED
static uint8 text_chunky_buf[40*8];
#endif
static uint16 mx[8]; // VIC registers
static uint8 mx8;
static uint8 my[8];
static uint8 ctrl1, ctrl2;
static uint8 lpx, lpy;
static uint8 me, mxe, mye, mdp, mmc;
static uint8 vbase;
static uint8 irq_flag, irq_mask;
static uint8 clx_spr, clx_bgr;
static uint8 ec, b0c, b1c, b2c, b3c, mm0, mm1;
static uint8 sc[8];
static uint8 *ram, *char_rom, *color_ram; // Pointers to RAM and ROM
static C64 *the_c64; // Pointer to C64
static C64Display *the_display; // Pointer to C64Display
static MOS6510 *the_cpu; // Pointer to 6510
static uint8 colors[256]; // Indices of the 16 C64 colors (16 times mirrored to avoid "& 0x0f")
static uint8 ec_color, b0c_color, b1c_color, b2c_color, b3c_color; // Indices for exterior/background colors
static uint8 mm0_color, mm1_color; // Indices for MOB multicolors
static uint8 spr_color[8]; // Indices for MOB colors
static uint32 ec_color_long; // ec_color expanded to 32 bits
static uint8 matrix_line[40]; // Buffer for video line, read in Bad Lines
static uint8 color_line[40]; // Buffer for color line, read in Bad Lines
#ifdef __POWERPC__
static double chunky_tmp[DISPLAY_X/8]; // Temporary line buffer for GameKit speedup
#endif
static uint8 *chunky_line_start; // Pointer to start of current line in bitmap buffer
static int xmod; // Number of bytes per row
static uint8 *matrix_base; // Video matrix base
static uint8 *char_base; // Character generator base
static uint8 *bitmap_base; // Bitmap base
static uint16 raster_y; // Current raster line
static uint16 irq_raster; // Interrupt raster line
static uint16 dy_start; // Comparison values for border logic
static uint16 dy_stop;
static uint16 rc; // Row counter
static uint16 vc; // Video counter
static uint16 vc_base; // Video counter base
static uint16 x_scroll; // X scroll value
static uint16 y_scroll; // Y scroll value
static uint16 cia_vabase; // CIA VA14/15 video base
static int display_idx; // Index of current display mode
static int skip_counter; // Counter for frame-skipping
static uint16 mc[8]; // Sprite data counters
static uint8 sprite_on; // 8 Flags: Sprite display/DMA active
static uint8 spr_coll_buf[0x180]; // Buffer for sprite-sprite collisions and priorities
static uint8 fore_mask_buf[0x180/8]; // Foreground mask for sprite-graphics collisions and priorities
static bool display_state; // true: Display state, false: Idle state
static bool border_on; // Flag: Upper/lower border on
static bool border_40_col; // Flag: 40 column border
static bool frame_skipped; // Flag: Frame is being skipped
static uint8 bad_lines_enabled; // Flag: Bad Lines enabled for this frame
static bool lp_triggered; // Flag: Lightpen was triggered in this frame
#endif
/*
* Constructor: Initialize variables
*/
static void init_text_color_table(uint8 *colors)
{
for (int i = 0; i < 16; i++)
for (int j = 0; j < 16; j++)
for (int k = 0; k < 256; k++) {
#ifdef __POWERPC__
TextColorTable[i][j][k].a.a = colors[k & 128 ? i : j];
TextColorTable[i][j][k].a.b = colors[k & 64 ? i : j];
TextColorTable[i][j][k].a.c = colors[k & 32 ? i : j];
TextColorTable[i][j][k].a.d = colors[k & 16 ? i : j];
TextColorTable[i][j][k].a.e = colors[k & 8 ? i : j];
TextColorTable[i][j][k].a.f = colors[k & 4 ? i : j];
TextColorTable[i][j][k].a.g = colors[k & 2 ? i : j];
TextColorTable[i][j][k].a.h = colors[k & 1 ? i : j];
#else
TextColorTable[i][j][k][0].a.a = colors[k & 128 ? i : j];
TextColorTable[i][j][k][0].a.b = colors[k & 64 ? i : j];
TextColorTable[i][j][k][0].a.c = colors[k & 32 ? i : j];
TextColorTable[i][j][k][0].a.d = colors[k & 16 ? i : j];
TextColorTable[i][j][k][1].a.a = colors[k & 8 ? i : j];
TextColorTable[i][j][k][1].a.b = colors[k & 4 ? i : j];
TextColorTable[i][j][k][1].a.c = colors[k & 2 ? i : j];
TextColorTable[i][j][k][1].a.d = colors[k & 1 ? i : j];
#endif
}
}
MOS6569::MOS6569(C64 *c64, C64Display *disp, MOS6510 *CPU, uint8 *RAM, uint8 *Char, uint8 *Color)
#ifndef GLOBAL_VARS
: ram(RAM), char_rom(Char), color_ram(Color), the_c64(c64), the_display(disp), the_cpu(CPU)
#endif
{
int i;
// Set pointers
#ifdef GLOBAL_VARS
the_c64 = c64;
the_display = disp;
the_cpu = CPU;
ram = RAM;
char_rom = Char;
color_ram = Color;
#endif
matrix_base = RAM;
char_base = RAM;
bitmap_base = RAM;
// Get bitmap info
chunky_line_start = disp->BitmapBase();
xmod = disp->BitmapXMod();
// Initialize VIC registers
mx8 = 0;
ctrl1 = ctrl2 = 0;
lpx = lpy = 0;
me = mxe = mye = mdp = mmc = 0;
vbase = irq_flag = irq_mask = 0;
clx_spr = clx_bgr = 0;
cia_vabase = 0;
ec = b0c = b1c = b2c = b3c = mm0 = mm1 = 0;
for (i=0; i<8; i++) mx[i] = my[i] = sc[i] = 0;
// Initialize other variables
raster_y = 0xffff;
rc = 7;
irq_raster = vc = vc_base = x_scroll = y_scroll = 0;
dy_start = ROW24_YSTART;
dy_stop = ROW24_YSTOP;
display_idx = 0;
display_state = false;
border_on = false;
lp_triggered = false;
sprite_on = 0;
for (i=0; i<8; i++)
mc[i] = 63;
frame_skipped = false;
skip_counter = 1;
// Clear foreground mask
memset(fore_mask_buf, 0, DISPLAY_X/8);
// Preset colors to black
disp->InitColors(colors);
init_text_color_table(colors);
ec_color = b0c_color = b1c_color = b2c_color = b3c_color = mm0_color = mm1_color = colors[0];
ec_color_long = (ec_color << 24) | (ec_color << 16) | (ec_color << 8) | ec_color;
for (i=0; i<8; i++) spr_color[i] = colors[0];
}
/*
* Reinitialize the colors table for when the palette has changed
*/
void MOS6569::ReInitColors(void)
{
int i;
// Build inverse color table.
uint8 xlate_colors[256];
memset(xlate_colors, 0, sizeof(xlate_colors));
for (i = 0; i < 16; i++)
xlate_colors[colors[i]] = i;
// Get the new colors.
the_display->InitColors(colors);
init_text_color_table(colors);
// Build color translation table.
for (i = 0; i < 256; i++)
xlate_colors[i] = colors[xlate_colors[i]];
// Translate all the old colors variables.
ec_color = colors[ec];
ec_color_long = ec_color | (ec_color << 8) | (ec_color << 16) | (ec_color << 24);
b0c_color = colors[b0c];
b1c_color = colors[b1c];
b2c_color = colors[b2c];
b3c_color = colors[b3c];
mm0_color = colors[mm0];
mm1_color = colors[mm1];
for (i = 0; i < 8; i++)
spr_color[i] = colors[sc[i]];
mc_color_lookup[0] = b0c_color | (b0c_color << 8);
mc_color_lookup[1] = b1c_color | (b1c_color << 8);
mc_color_lookup[2] = b2c_color | (b2c_color << 8);
// Translate the chunky buffer.
uint8 *scanline = the_display->BitmapBase();
for (int y = 0; y < DISPLAY_Y; y++) {
for (int x = 0; x < DISPLAY_X; x++)
scanline[x] = xlate_colors[scanline[x]];
scanline += xmod;
}
}
#ifdef GLOBAL_VARS
static void make_mc_table(void)
#else
void MOS6569::make_mc_table(void)
#endif
{
mc_color_lookup[0] = b0c_color | (b0c_color << 8);
mc_color_lookup[1] = b1c_color | (b1c_color << 8);
mc_color_lookup[2] = b2c_color | (b2c_color << 8);
}
/*
* Convert video address to pointer
*/
#ifdef GLOBAL_VARS
static inline uint8 *get_physical(uint16 adr)
#else
inline uint8 *MOS6569::get_physical(uint16 adr)
#endif
{
int va = adr | cia_vabase;
if ((va & 0x7000) == 0x1000)
return char_rom + (va & 0x0fff);
else
return ram + va;
}
/*
* Get VIC state
*/
void MOS6569::GetState(MOS6569State *vd)
{
int i;
vd->m0x = mx[0] & 0xff; vd->m0y = my[0];
vd->m1x = mx[1] & 0xff; vd->m1y = my[1];
vd->m2x = mx[2] & 0xff; vd->m2y = my[2];
vd->m3x = mx[3] & 0xff; vd->m3y = my[3];
vd->m4x = mx[4] & 0xff; vd->m4y = my[4];
vd->m5x = mx[5] & 0xff; vd->m5y = my[5];
vd->m6x = mx[6] & 0xff; vd->m6y = my[6];
vd->m7x = mx[7] & 0xff; vd->m7y = my[7];
vd->mx8 = mx8;
vd->ctrl1 = (ctrl1 & 0x7f) | ((raster_y & 0x100) >> 1);
vd->raster = raster_y & 0xff;
vd->lpx = lpx; vd->lpy = lpy;
vd->ctrl2 = ctrl2;
vd->vbase = vbase;
vd->irq_flag = irq_flag;
vd->irq_mask = irq_mask;
vd->me = me; vd->mxe = mxe; vd->mye = mye; vd->mdp = mdp; vd->mmc = mmc;
vd->mm = clx_spr; vd->md = clx_bgr;
vd->ec = ec;
vd->b0c = b0c; vd->b1c = b1c; vd->b2c = b2c; vd->b3c = b3c;
vd->mm0 = mm0; vd->mm1 = mm1;
vd->m0c = sc[0]; vd->m1c = sc[1];
vd->m2c = sc[2]; vd->m3c = sc[3];
vd->m4c = sc[4]; vd->m5c = sc[5];
vd->m6c = sc[6]; vd->m7c = sc[7];
vd->pad0 = 0;
vd->irq_raster = irq_raster;
vd->vc = vc;
vd->vc_base = vc_base;
vd->rc = rc;
vd->spr_dma = vd->spr_disp = sprite_on;
for (i=0; i<8; i++)
vd->mc[i] = vd->mc_base[i] = mc[i];
vd->display_state = display_state;
vd->bad_line = raster_y >= FIRST_DMA_LINE && raster_y <= LAST_DMA_LINE && ((raster_y & 7) == y_scroll) && bad_lines_enabled;
vd->bad_line_enable = bad_lines_enabled;
vd->lp_triggered = lp_triggered;
vd->border_on = border_on;
vd->bank_base = cia_vabase;
vd->matrix_base = ((vbase & 0xf0) << 6) | cia_vabase;
vd->char_base = ((vbase & 0x0e) << 10) | cia_vabase;
vd->bitmap_base = ((vbase & 0x08) << 10) | cia_vabase;
for (i=0; i<8; i++)
vd->sprite_base[i] = (matrix_base[0x3f8 + i] << 6) | cia_vabase;
vd->cycle = 1;
vd->raster_x = 0;
vd->ml_index = 0;
vd->ref_cnt = 0xff;
vd->last_vic_byte = 0;
vd->ud_border_on = border_on;
}
/*
* Set VIC state (only works if in VBlank)
*/
void MOS6569::SetState(MOS6569State *vd)
{
int i, j;
mx[0] = vd->m0x; my[0] = vd->m0y;
mx[1] = vd->m1x; my[1] = vd->m1y;
mx[2] = vd->m2x; my[2] = vd->m2y;
mx[3] = vd->m3x; my[3] = vd->m3y;
mx[4] = vd->m4x; my[4] = vd->m4y;
mx[5] = vd->m5x; my[5] = vd->m5y;
mx[6] = vd->m6x; my[6] = vd->m6y;
mx[7] = vd->m7x; my[7] = vd->m7y;
mx8 = vd->mx8;
for (i=0, j=1; i<8; i++, j<<=1) {
if (mx8 & j)
mx[i] |= 0x100;
else
mx[i] &= 0xff;
}
ctrl1 = vd->ctrl1;
ctrl2 = vd->ctrl2;
x_scroll = ctrl2 & 7;
y_scroll = ctrl1 & 7;
if (ctrl1 & 8) {
dy_start = ROW25_YSTART;
dy_stop = ROW25_YSTOP;
} else {
dy_start = ROW24_YSTART;
dy_stop = ROW24_YSTOP;
}
border_40_col = ctrl2 & 8;
display_idx = ((ctrl1 & 0x60) | (ctrl2 & 0x10)) >> 4;
raster_y = 0;
lpx = vd->lpx; lpy = vd->lpy;
vbase = vd->vbase;
cia_vabase = vd->bank_base;
matrix_base = get_physical((vbase & 0xf0) << 6);
char_base = get_physical((vbase & 0x0e) << 10);
bitmap_base = get_physical((vbase & 0x08) << 10);
irq_flag = vd->irq_flag;
irq_mask = vd->irq_mask;
me = vd->me; mxe = vd->mxe; mye = vd->mye; mdp = vd->mdp; mmc = vd->mmc;
clx_spr = vd->mm; clx_bgr = vd->md;
ec = vd->ec;
ec_color = colors[ec];
ec_color_long = (ec_color << 24) | (ec_color << 16) | (ec_color << 8) | ec_color;
b0c = vd->b0c; b1c = vd->b1c; b2c = vd->b2c; b3c = vd->b3c;
b0c_color = colors[b0c];
b1c_color = colors[b1c];
b2c_color = colors[b2c];
b3c_color = colors[b3c];
make_mc_table();
mm0 = vd->mm0; mm1 = vd->mm1;
mm0_color = colors[mm0];
mm1_color = colors[mm1];
sc[0] = vd->m0c; sc[1] = vd->m1c;
sc[2] = vd->m2c; sc[3] = vd->m3c;
sc[4] = vd->m4c; sc[5] = vd->m5c;
sc[6] = vd->m6c; sc[7] = vd->m7c;
for (i=0; i<8; i++)
spr_color[i] = colors[sc[i]];
irq_raster = vd->irq_raster;
vc = vd->vc;
vc_base = vd->vc_base;
rc = vd->rc;
sprite_on = vd->spr_dma;
for (i=0; i<8; i++)
mc[i] = vd->mc[i];
display_state = vd->display_state;
bad_lines_enabled = vd->bad_line_enable;
lp_triggered = vd->lp_triggered;
border_on = vd->border_on;
}
/*
* Trigger raster IRQ
*/
#ifdef GLOBAL_VARS
static inline void raster_irq(void)
#else
inline void MOS6569::raster_irq(void)
#endif
{
irq_flag |= 0x01;
if (irq_mask & 0x01) {
irq_flag |= 0x80;
the_cpu->TriggerVICIRQ();
}
}
/*
* Read from VIC register
*/
uint8 MOS6569::ReadRegister(uint16 adr)
{
switch (adr) {
case 0x00: case 0x02: case 0x04: case 0x06:
case 0x08: case 0x0a: case 0x0c: case 0x0e:
return mx[adr >> 1];
case 0x01: case 0x03: case 0x05: case 0x07:
case 0x09: case 0x0b: case 0x0d: case 0x0f:
return my[adr >> 1];
case 0x10: // Sprite X position MSB
return mx8;
case 0x11: // Control register 1
return (ctrl1 & 0x7f) | ((raster_y & 0x100) >> 1);
case 0x12: // Raster counter
return raster_y;
case 0x13: // Light pen X
return lpx;
case 0x14: // Light pen Y
return lpy;
case 0x15: // Sprite enable
return me;
case 0x16: // Control register 2
return ctrl2 | 0xc0;
case 0x17: // Sprite Y expansion
return mye;
case 0x18: // Memory pointers
return vbase | 0x01;
case 0x19: // IRQ flags
return irq_flag | 0x70;
case 0x1a: // IRQ mask
return irq_mask | 0xf0;
case 0x1b: // Sprite data priority
return mdp;
case 0x1c: // Sprite multicolor
return mmc;
case 0x1d: // Sprite X expansion
return mxe;
case 0x1e:{ // Sprite-sprite collision
uint8 ret = clx_spr;
clx_spr = 0; // Read and clear
return ret;
}
case 0x1f:{ // Sprite-background collision
uint8 ret = clx_bgr;
clx_bgr = 0; // Read and clear
return ret;
}
case 0x20: return ec | 0xf0;
case 0x21: return b0c | 0xf0;
case 0x22: return b1c | 0xf0;
case 0x23: return b2c | 0xf0;
case 0x24: return b3c | 0xf0;
case 0x25: return mm0 | 0xf0;
case 0x26: return mm1 | 0xf0;
case 0x27: case 0x28: case 0x29: case 0x2a:
case 0x2b: case 0x2c: case 0x2d: case 0x2e:
return sc[adr - 0x27] | 0xf0;
default:
return 0xff;
}
}
/*
* Write to VIC register
*/
void MOS6569::WriteRegister(uint16 adr, uint8 byte)
{
switch (adr) {
case 0x00: case 0x02: case 0x04: case 0x06:
case 0x08: case 0x0a: case 0x0c: case 0x0e:
mx[adr >> 1] = (mx[adr >> 1] & 0xff00) | byte;
break;
case 0x10:{
int i, j;
mx8 = byte;
for (i=0, j=1; i<8; i++, j<<=1) {
if (mx8 & j)
mx[i] |= 0x100;
else
mx[i] &= 0xff;
}
break;
}
case 0x01: case 0x03: case 0x05: case 0x07:
case 0x09: case 0x0b: case 0x0d: case 0x0f:
my[adr >> 1] = byte;
break;
case 0x11:{ // Control register 1
ctrl1 = byte;
y_scroll = byte & 7;
uint16 new_irq_raster = (irq_raster & 0xff) | ((byte & 0x80) << 1);
if (irq_raster != new_irq_raster && raster_y == new_irq_raster)
raster_irq();
irq_raster = new_irq_raster;
if (byte & 8) {
dy_start = ROW25_YSTART;
dy_stop = ROW25_YSTOP;
} else {
dy_start = ROW24_YSTART;
dy_stop = ROW24_YSTOP;
}
display_idx = ((ctrl1 & 0x60) | (ctrl2 & 0x10)) >> 4;
break;
}
case 0x12:{ // Raster counter
uint16 new_irq_raster = (irq_raster & 0xff00) | byte;
if (irq_raster != new_irq_raster && raster_y == new_irq_raster)
raster_irq();
irq_raster = new_irq_raster;
break;
}
case 0x15: // Sprite enable
me = byte;
break;
case 0x16: // Control register 2
ctrl2 = byte;
x_scroll = byte & 7;
border_40_col = byte & 8;
display_idx = ((ctrl1 & 0x60) | (ctrl2 & 0x10)) >> 4;
break;
case 0x17: // Sprite Y expansion
mye = byte;
break;
case 0x18: // Memory pointers
vbase = byte;
matrix_base = get_physical((byte & 0xf0) << 6);
char_base = get_physical((byte & 0x0e) << 10);
bitmap_base = get_physical((byte & 0x08) << 10);
break;
case 0x19: // IRQ flags
irq_flag = irq_flag & (~byte & 0x0f);
the_cpu->ClearVICIRQ(); // Clear interrupt (hack!)
if (irq_flag & irq_mask) // Set master bit if allowed interrupt still pending
irq_flag |= 0x80;
break;
case 0x1a: // IRQ mask
irq_mask = byte & 0x0f;
if (irq_flag & irq_mask) { // Trigger interrupt if pending and now allowed
irq_flag |= 0x80;
the_cpu->TriggerVICIRQ();
} else {
irq_flag &= 0x7f;
the_cpu->ClearVICIRQ();
}
break;
case 0x1b: // Sprite data priority
mdp = byte;
break;
case 0x1c: // Sprite multicolor
mmc = byte;
break;
case 0x1d: // Sprite X expansion
mxe = byte;
break;
case 0x20:
ec_color = colors[ec = byte];
ec_color_long = (ec_color << 24) | (ec_color << 16) | (ec_color << 8) | ec_color;
break;
case 0x21:
if (b0c != byte) {
b0c_color = colors[b0c = byte & 0xF];
make_mc_table();
}
break;
case 0x22:
if (b1c != byte) {
b1c_color = colors[b1c = byte & 0xF];
make_mc_table();
}
break;
case 0x23:
if (b2c != byte) {
b2c_color = colors[b2c = byte & 0xF];
make_mc_table();
}
break;
case 0x24: b3c_color = colors[b3c = byte & 0xF]; break;
case 0x25: mm0_color = colors[mm0 = byte]; break;
case 0x26: mm1_color = colors[mm1 = byte]; break;
case 0x27: case 0x28: case 0x29: case 0x2a:
case 0x2b: case 0x2c: case 0x2d: case 0x2e:
spr_color[adr - 0x27] = colors[sc[adr - 0x27] = byte];
break;
}
}
/*
* CIA VA14/15 has changed
*/
void MOS6569::ChangedVA(uint16 new_va)
{
cia_vabase = new_va << 14;
WriteRegister(0x18, vbase); // Force update of memory pointers
}
/*
* Trigger lightpen interrupt, latch lightpen coordinates
*/
void MOS6569::TriggerLightpen(void)
{
if (!lp_triggered) { // Lightpen triggers only once per frame
lp_triggered = true;
lpx = 0; // Latch current coordinates
lpy = raster_y;
irq_flag |= 0x08; // Trigger IRQ
if (irq_mask & 0x08) {
irq_flag |= 0x80;
the_cpu->TriggerVICIRQ();
}
}
}
/*
* VIC vertical blank: Reset counters and redraw screen
*/
#ifdef GLOBAL_VARS
static inline void vblank(void)
#else
inline void MOS6569::vblank(void)
#endif
{
raster_y = vc_base = 0;
lp_triggered = false;
if (!(frame_skipped = --skip_counter))
skip_counter = ThePrefs.SkipFrames;
the_c64->VBlank(!frame_skipped);
// Get bitmap pointer for next frame. This must be done
// after calling the_c64->VBlank() because the preferences
// and screen configuration may have been changed there
chunky_line_start = the_display->BitmapBase();
xmod = the_display->BitmapXMod();
}
#ifdef __riscos__
#include "el_Acorn.h"
#else
#ifdef GLOBAL_VARS
static inline void el_std_text(uint8 *p, uint8 *q, uint8 *r)
#else
inline void MOS6569::el_std_text(uint8 *p, uint8 *q, uint8 *r)
#endif
{
unsigned int b0cc = b0c;
#ifdef __POWERPC__
double *dp = (double *)p - 1;
#else
uint32 *lp = (uint32 *)p;
#endif
uint8 *cp = color_line;
uint8 *mp = matrix_line;
// Loop for 40 characters
for (int i=0; i<40; i++) {
uint8 color = cp[i];
uint8 data = r[i] = q[mp[i] << 3];
#ifdef __POWERPC__
*++dp = TextColorTable[color][b0cc][data].b;
#else
*lp++ = TextColorTable[color][b0cc][data][0].b;
*lp++ = TextColorTable[color][b0cc][data][1].b;
#endif
}
}
#ifdef GLOBAL_VARS
static inline void el_mc_text(uint8 *p, uint8 *q, uint8 *r)
#else
inline void MOS6569::el_mc_text(uint8 *p, uint8 *q, uint8 *r)
#endif
{
uint16 *wp = (uint16 *)p;
uint8 *cp = color_line;
uint8 *mp = matrix_line;
uint16 *mclp = mc_color_lookup;
// Loop for 40 characters
for (int i=0; i<40; i++) {
uint8 data = q[mp[i] << 3];
if (cp[i] & 8) {
uint8 color = colors[cp[i] & 7];
r[i] = (data & 0xaa) | (data & 0xaa) >> 1;
mclp[3] = color | (color << 8);
*wp++ = mclp[(data >> 6) & 3];
*wp++ = mclp[(data >> 4) & 3];
*wp++ = mclp[(data >> 2) & 3];
*wp++ = mclp[(data >> 0) & 3];
} else { // Standard mode in multicolor mode
uint8 color = cp[i];
r[i] = data;
#ifdef __POWERPC__
*(double *)wp = TextColorTable[color][b0c][data].b;
wp += 4;
#else
*(uint32 *)wp = TextColorTable[color][b0c][data][0].b;
wp += 2;
*(uint32 *)wp = TextColorTable[color][b0c][data][1].b;
wp += 2;
#endif
}
}
}
#ifdef GLOBAL_VARS
static inline void el_std_bitmap(uint8 *p, uint8 *q, uint8 *r)
#else
inline void MOS6569::el_std_bitmap(uint8 *p, uint8 *q, uint8 *r)
#endif
{
#ifdef __POWERPC__
double *dp = (double *)p-1;
#else
uint32 *lp = (uint32 *)p;
#endif
uint8 *mp = matrix_line;
// Loop for 40 characters
for (int i=0; i<40; i++, q+=8) {
uint8 data = r[i] = *q;
uint8 color = mp[i] >> 4;
uint8 bcolor = mp[i] & 15;
#ifdef __POWERPC__
*++dp = TextColorTable[color][bcolor][data].b;
#else
*lp++ = TextColorTable[color][bcolor][data][0].b;
*lp++ = TextColorTable[color][bcolor][data][1].b;
#endif
}
}
#ifdef GLOBAL_VARS
static inline void el_mc_bitmap(uint8 *p, uint8 *q, uint8 *r)
#else
inline void MOS6569::el_mc_bitmap(uint8 *p, uint8 *q, uint8 *r)
#endif
{
uint16 lookup[4];
uint16 *wp = (uint16 *)p - 1;
uint8 *cp = color_line;
uint8 *mp = matrix_line;
#ifdef __GNU_C__
&lookup; /* Statement with no effect other than preventing GCC from
* putting the array in a register, which generates
* spectacularly bad code. */
#endif
lookup[0] = (b0c_color << 8) | b0c_color;
// Loop for 40 characters
for (int i=0; i<40; i++, q+=8) {
uint8 color, acolor, bcolor;
color = colors[mp[i] >> 4];
lookup[1] = (color << 8) | color;
bcolor = colors[mp[i]];
lookup[2] = (bcolor << 8) | bcolor;
acolor = colors[cp[i]];
lookup[3] = (acolor << 8) | acolor;
uint8 data = *q;
r[i] = (data & 0xaa) | (data & 0xaa) >> 1;
*++wp = lookup[(data >> 6) & 3];
*++wp = lookup[(data >> 4) & 3];
*++wp = lookup[(data >> 2) & 3];
*++wp = lookup[(data >> 0) & 3];
}
}
#ifdef GLOBAL_VARS
static inline void el_ecm_text(uint8 *p, uint8 *q, uint8 *r)
#else
inline void MOS6569::el_ecm_text(uint8 *p, uint8 *q, uint8 *r)
#endif
{
#ifdef __POWERPC__
double *dp = (double *)p - 1;
#else
uint32 *lp = (uint32 *)p;
#endif
uint8 *cp = color_line;
uint8 *mp = matrix_line;
uint8 *bcp = &b0c;
// Loop for 40 characters
for (int i=0; i<40; i++) {
uint8 data = r[i] = mp[i];
uint8 color = cp[i];
uint8 bcolor = bcp[(data >> 6) & 3];
data = q[(data & 0x3f) << 3];
#ifdef __POWERPC__
*++dp = TextColorTable[color][bcolor][data].b;
#else
*lp++ = TextColorTable[color][bcolor][data][0].b;
*lp++ = TextColorTable[color][bcolor][data][1].b;
#endif
}
}
#ifdef GLOBAL_VARS
static inline void el_std_idle(uint8 *p, uint8 *r)
#else
inline void MOS6569::el_std_idle(uint8 *p, uint8 *r)
#endif
{
#ifdef __POWERPC__
uint8 data = *get_physical(ctrl1 & 0x40 ? 0x39ff : 0x3fff);
double *dp = (double *)p - 1;
double conv = TextColorTable[0][b0c][data].b;
r--;
for (int i=0; i<40; i++) {
*++dp = conv;
*++r = data;
}
#else
uint8 data = *get_physical(ctrl1 & 0x40 ? 0x39ff : 0x3fff);
uint32 *lp = (uint32 *)p;
uint32 conv0 = TextColorTable[0][b0c][data][0].b;
uint32 conv1 = TextColorTable[0][b0c][data][1].b;
for (int i=0; i<40; i++) {
*lp++ = conv0;
*lp++ = conv1;
*r++ = data;
}
#endif
}
#ifdef GLOBAL_VARS
static inline void el_mc_idle(uint8 *p, uint8 *r)
#else
inline void MOS6569::el_mc_idle(uint8 *p, uint8 *r)
#endif
{
uint8 data = *get_physical(0x3fff);
uint32 *lp = (uint32 *)p - 1;
r--;
uint16 lookup[4];
lookup[0] = (b0c_color << 8) | b0c_color;
lookup[1] = lookup[2] = lookup[3] = colors[0];
uint16 conv0 = (lookup[(data >> 6) & 3] << 16) | lookup[(data >> 4) & 3];
uint16 conv1 = (lookup[(data >> 2) & 3] << 16) | lookup[(data >> 0) & 3];
for (int i=0; i<40; i++) {
*++lp = conv0;
*++lp = conv1;
*++r = data;
}
}
#endif //__riscos__
#ifdef GLOBAL_VARS
static inline void el_sprites(uint8 *chunky_ptr)
#else
inline void MOS6569::el_sprites(uint8 *chunky_ptr)
#endif
{
int i;
int snum, sbit; // Sprite number/bit mask
int spr_coll=0, gfx_coll=0;
// Draw each active sprite
for (snum=0, sbit=1; snum<8; snum++, sbit<<=1)
if ((sprite_on & sbit) && mx[snum] < DISPLAY_X-32) {
int spr_mask_pos; // Sprite bit position in fore_mask_buf
uint32 sdata, fore_mask;
uint8 *p = chunky_ptr + mx[snum] + 8;
uint8 *q = spr_coll_buf + mx[snum] + 8;
uint8 *sdatap = get_physical(matrix_base[0x3f8 + snum] << 6 | mc[snum]);
sdata = (*sdatap << 24) | (*(sdatap+1) << 16) | (*(sdatap+2) << 8);
uint8 color = spr_color[snum];
spr_mask_pos = mx[snum] + 8 - x_scroll;
uint8 *fmbp = fore_mask_buf + (spr_mask_pos / 8);
int sshift = spr_mask_pos & 7;
fore_mask = (((*(fmbp+0) << 24) | (*(fmbp+1) << 16) | (*(fmbp+2) << 8)
| (*(fmbp+3))) << sshift) | (*(fmbp+4) >> (8-sshift));
if (mxe & sbit) { // X-expanded
if (mx[snum] >= DISPLAY_X-56)
continue;
uint32 sdata_l = 0, sdata_r = 0, fore_mask_r;
fore_mask_r = (((*(fmbp+4) << 24) | (*(fmbp+5) << 16) | (*(fmbp+6) << 8)
| (*(fmbp+7))) << sshift) | (*(fmbp+8) >> (8-sshift));
if (mmc & sbit) { // Multicolor mode
uint32 plane0_l, plane0_r, plane1_l, plane1_r;
// Expand sprite data
sdata_l = MultiExpTable[sdata >> 24 & 0xff] << 16 | MultiExpTable[sdata >> 16 & 0xff];
sdata_r = MultiExpTable[sdata >> 8 & 0xff] << 16;
// Convert sprite chunky pixels to bitplanes
plane0_l = (sdata_l & 0x55555555) | (sdata_l & 0x55555555) << 1;
plane1_l = (sdata_l & 0xaaaaaaaa) | (sdata_l & 0xaaaaaaaa) >> 1;
plane0_r = (sdata_r & 0x55555555) | (sdata_r & 0x55555555) << 1;
plane1_r = (sdata_r & 0xaaaaaaaa) | (sdata_r & 0xaaaaaaaa) >> 1;
// Collision with graphics?
if ((fore_mask & (plane0_l | plane1_l)) || (fore_mask_r & (plane0_r | plane1_r))) {
gfx_coll |= sbit;
if (mdp & sbit) {
plane0_l &= ~fore_mask; // Mask sprite if in background
plane1_l &= ~fore_mask;
plane0_r &= ~fore_mask_r;
plane1_r &= ~fore_mask_r;
}
}
// Paint sprite
for (i=0; i<32; i++, plane0_l<<=1, plane1_l<<=1) {
uint8 col;
if (plane1_l & 0x80000000) {
if (plane0_l & 0x80000000)
col = mm1_color;
else
col = color;
} else {
if (plane0_l & 0x80000000)
col = mm0_color;
else
continue;
}
if (q[i])
spr_coll |= q[i] | sbit;
else {
p[i] = col;
q[i] = sbit;
}
}
for (; i<48; i++, plane0_r<<=1, plane1_r<<=1) {
uint8 col;
if (plane1_r & 0x80000000) {
if (plane0_r & 0x80000000)
col = mm1_color;
else
col = color;
} else {
if (plane0_r & 0x80000000)
col = mm0_color;
else
continue;
}
if (q[i])
spr_coll |= q[i] | sbit;
else {
p[i] = col;
q[i] = sbit;
}
}
} else { // Standard mode
// Expand sprite data
sdata_l = ExpTable[sdata >> 24 & 0xff] << 16 | ExpTable[sdata >> 16 & 0xff];
sdata_r = ExpTable[sdata >> 8 & 0xff] << 16;
// Collision with graphics?
if ((fore_mask & sdata_l) || (fore_mask_r & sdata_r)) {
gfx_coll |= sbit;
if (mdp & sbit) {
sdata_l &= ~fore_mask; // Mask sprite if in background
sdata_r &= ~fore_mask_r;
}
}
// Paint sprite
for (i=0; i<32; i++, sdata_l<<=1)
if (sdata_l & 0x80000000) {
if (q[i]) // Collision with sprite?
spr_coll |= q[i] | sbit;
else { // Draw pixel if no collision
p[i] = color;
q[i] = sbit;
}
}
for (; i<48; i++, sdata_r<<=1)
if (sdata_r & 0x80000000) {
if (q[i]) // Collision with sprite?
spr_coll |= q[i] | sbit;
else { // Draw pixel if no collision
p[i] = color;
q[i] = sbit;
}
}
}
} else // Unexpanded
if (mmc & sbit) { // Multicolor mode
uint32 plane0, plane1;
// Convert sprite chunky pixels to bitplanes
plane0 = (sdata & 0x55555555) | (sdata & 0x55555555) << 1;
plane1 = (sdata & 0xaaaaaaaa) | (sdata & 0xaaaaaaaa) >> 1;
// Collision with graphics?
if (fore_mask & (plane0 | plane1)) {
gfx_coll |= sbit;
if (mdp & sbit) {
plane0 &= ~fore_mask; // Mask sprite if in background
plane1 &= ~fore_mask;
}
}
// Paint sprite
for (i=0; i<24; i++, plane0<<=1, plane1<<=1) {
uint8 col;
if (plane1 & 0x80000000) {
if (plane0 & 0x80000000)
col = mm1_color;
else
col = color;
} else {
if (plane0 & 0x80000000)
col = mm0_color;
else
continue;
}
if (q[i])
spr_coll |= q[i] | sbit;
else {
p[i] = col;
q[i] = sbit;
}
}
} else { // Standard mode
// Collision with graphics?
if (fore_mask & sdata) {
gfx_coll |= sbit;
if (mdp & sbit)
sdata &= ~fore_mask; // Mask sprite if in background
}
// Paint sprite
for (i=0; i<24; i++, sdata<<=1)
if (sdata & 0x80000000) {
if (q[i]) { // Collision with sprite?
spr_coll |= q[i] | sbit;
} else { // Draw pixel if no collision
p[i] = color;
q[i] = sbit;
}
}
}
}
if (ThePrefs.SpriteCollisions) {
// Check sprite-sprite collisions
if (clx_spr)
clx_spr |= spr_coll;
else {
clx_spr |= spr_coll;
irq_flag |= 0x04;
if (irq_mask & 0x04) {
irq_flag |= 0x80;
the_cpu->TriggerVICIRQ();
}
}
// Check sprite-background collisions
if (clx_bgr)
clx_bgr |= gfx_coll;
else {
clx_bgr |= gfx_coll;
irq_flag |= 0x02;
if (irq_mask & 0x02) {
irq_flag |= 0x80;
the_cpu->TriggerVICIRQ();
}
}
}
}
#ifdef GLOBAL_VARS
static inline int el_update_mc(int raster)
#else
inline int MOS6569::el_update_mc(int raster)
#endif
{
int i, j;
int cycles_used = 0;
uint8 spron = sprite_on;
uint8 spren = me;
uint8 sprye = mye;
uint8 raster8bit = raster;
uint16 *mcp = mc;
uint8 *myp = my;
// Increment sprite data counters
for (i=0, j=1; i<8; i++, j<<=1, mcp++, myp++) {
// Sprite enabled?
if (spren & j)
// Yes, activate if Y position matches raster counter
if (*myp == (raster8bit & 0xff)) {
*mcp = 0;
spron |= j;
} else
goto spr_off;
else
spr_off:
// No, turn sprite off when data counter exceeds 60
// and increment counter
if (*mcp != 63) {
if (sprye & j) { // Y expansion
if (!((*myp ^ raster8bit) & 1)) {
*mcp += 3;
cycles_used += 2;
if (*mcp == 63)
spron &= ~j;
}
} else {
*mcp += 3;
cycles_used += 2;
if (*mcp == 63)
spron &= ~j;
}
}
}
sprite_on = spron;
return cycles_used;
}
#ifdef __POWERPC__
static asm void fastcopy(register uchar *dst, register uchar *src);
static asm void fastcopy(register uchar *dst, register uchar *src)
{
lfd fp0,0(src)
lfd fp1,8(src)
lfd fp2,16(src)
lfd fp3,24(src)
lfd fp4,32(src)
lfd fp5,40(src)
lfd fp6,48(src)
lfd fp7,56(src)
addi src,src,64
stfd fp0,0(dst)
stfd fp1,8(dst)
stfd fp2,16(dst)
stfd fp3,24(dst)
stfd fp4,32(dst)
stfd fp5,40(dst)
stfd fp6,48(dst)
stfd fp7,56(dst)
addi dst,dst,64
lfd fp0,0(src)
lfd fp1,8(src)
lfd fp2,16(src)
lfd fp3,24(src)
lfd fp4,32(src)
lfd fp5,40(src)
lfd fp6,48(src)
lfd fp7,56(src)
addi src,src,64
stfd fp0,0(dst)
stfd fp1,8(dst)
stfd fp2,16(dst)
stfd fp3,24(dst)
stfd fp4,32(dst)
stfd fp5,40(dst)
stfd fp6,48(dst)
stfd fp7,56(dst)
addi dst,dst,64
lfd fp0,0(src)
lfd fp1,8(src)
lfd fp2,16(src)
lfd fp3,24(src)
lfd fp4,32(src)
lfd fp5,40(src)
lfd fp6,48(src)
lfd fp7,56(src)
addi src,src,64
stfd fp0,0(dst)
stfd fp1,8(dst)
stfd fp2,16(dst)
stfd fp3,24(dst)
stfd fp4,32(dst)
stfd fp5,40(dst)
stfd fp6,48(dst)
stfd fp7,56(dst)
addi dst,dst,64
lfd fp0,0(src)
lfd fp1,8(src)
lfd fp2,16(src)
lfd fp3,24(src)
lfd fp4,32(src)
lfd fp5,40(src)
lfd fp6,48(src)
lfd fp7,56(src)
addi src,src,64
stfd fp0,0(dst)
stfd fp1,8(dst)
stfd fp2,16(dst)
stfd fp3,24(dst)
stfd fp4,32(dst)
stfd fp5,40(dst)
stfd fp6,48(dst)
stfd fp7,56(dst)
addi dst,dst,64
lfd fp0,0(src)
lfd fp1,8(src)
lfd fp2,16(src)
lfd fp3,24(src)
lfd fp4,32(src)
lfd fp5,40(src)
lfd fp6,48(src)
lfd fp7,56(src)
addi src,src,64
stfd fp0,0(dst)
stfd fp1,8(dst)
stfd fp2,16(dst)
stfd fp3,24(dst)
stfd fp4,32(dst)
stfd fp5,40(dst)
stfd fp6,48(dst)
stfd fp7,56(dst)
addi dst,dst,64
lfd fp0,0(src)
lfd fp1,8(src)
lfd fp2,16(src)
lfd fp3,24(src)
lfd fp4,32(src)
lfd fp5,40(src)
lfd fp6,48(src)
lfd fp7,56(src)
addi src,src,64
stfd fp0,0(dst)
stfd fp1,8(dst)
stfd fp2,16(dst)
stfd fp3,24(dst)
stfd fp4,32(dst)
stfd fp5,40(dst)
stfd fp6,48(dst)
stfd fp7,56(dst)
addi dst,dst,64
blr
}
#endif
/*
* Emulate one raster line
*/
int MOS6569::EmulateLine(void)
{
int cycles_left = ThePrefs.NormalCycles; // Cycles left for CPU
bool is_bad_line = false;
// Get raster counter into local variable for faster access and increment
unsigned int raster = raster_y+1;
// End of screen reached?
if (raster != TOTAL_RASTERS)
raster_y = raster;
else {
vblank();
raster = 0;
}
// Trigger raster IRQ if IRQ line reached
if (raster == irq_raster)
raster_irq();
// In line $30, the DEN bit controls if Bad Lines can occur
if (raster == 0x30)
bad_lines_enabled = ctrl1 & 0x10;
// Skip frame? Only calculate Bad Lines then
if (frame_skipped) {
if (raster >= FIRST_DMA_LINE && raster <= LAST_DMA_LINE && ((raster & 7) == y_scroll) && bad_lines_enabled) {
is_bad_line = true;
cycles_left = ThePrefs.BadLineCycles;
}
goto VIC_nop;
}
// Within the visible range?
if (raster >= FIRST_DISP_LINE && raster <= LAST_DISP_LINE) {
// Our output goes here
#ifdef __POWERPC__
uint8 *chunky_ptr = (uint8 *)chunky_tmp;
#else
uint8 *chunky_ptr = chunky_line_start;
#endif
// Set video counter
vc = vc_base;
// Bad Line condition?
if (raster >= FIRST_DMA_LINE && raster <= LAST_DMA_LINE && ((raster & 7) == y_scroll) && bad_lines_enabled) {
// Turn on display
display_state = is_bad_line = true;
cycles_left = ThePrefs.BadLineCycles;
rc = 0;
// Read and latch 40 bytes from video matrix and color RAM
uint8 *mp = matrix_line - 1;
uint8 *cp = color_line - 1;
int vc1 = vc - 1;
uint8 *mbp = matrix_base + vc1;
uint8 *crp = color_ram + vc1;
for (int i=0; i<40; i++) {
*++mp = *++mbp;
*++cp = *++crp;
}
}
// Handler upper/lower border
if (raster == dy_stop)
border_on = true;
if (raster == dy_start && (ctrl1 & 0x10)) // Don't turn off border if DEN bit cleared
border_on = false;
if (!border_on) {
// Display window contents
uint8 *p = chunky_ptr + COL40_XSTART; // Pointer in chunky display buffer
uint8 *r = fore_mask_buf + COL40_XSTART/8; // Pointer in foreground mask buffer
#ifdef ALIGNMENT_CHECK
uint8 *use_p = ((((int)p) & 3) == 0) ? p : text_chunky_buf;
#endif
{
p--;
uint8 b0cc = b0c_color;
int limit = x_scroll;
for (int i=0; i<limit; i++) // Background on the left if XScroll>0
*++p = b0cc;
p++;
}
if (display_state) {
switch (display_idx) {
case 0: // Standard text
#ifndef CAN_ACCESS_UNALIGNED
#ifdef ALIGNMENT_CHECK
el_std_text(use_p, char_base + rc, r);
if (use_p != p)
memcpy(p, use_p, 8*40);
#else
if (x_scroll) {
el_std_text(text_chunky_buf, char_base + rc, r);
memcpy(p, text_chunky_buf, 8*40);
} else
el_std_text(p, char_base + rc, r);
#endif
#else
el_std_text(p, char_base + rc, r);
#endif
break;
case 1: // Multicolor text
#ifndef CAN_ACCESS_UNALIGNED
#ifdef ALIGNMENT_CHECK
el_mc_text(use_p, char_base + rc, r);
if (use_p != p)
memcpy(p, use_p, 8*40);
#else
if (x_scroll) {
el_mc_text(text_chunky_buf, char_base + rc, r);
memcpy(p, text_chunky_buf, 8*40);
} else
el_mc_text(p, char_base + rc, r);
#endif
#else
el_mc_text(p, char_base + rc, r);
#endif
break;
case 2: // Standard bitmap
#ifndef CAN_ACCESS_UNALIGNED
#ifdef ALIGNMENT_CHECK
el_std_bitmap(use_p, bitmap_base + (vc << 3) + rc, r);
if (use_p != p)
memcpy(p, use_p, 8*40);
#else
if (x_scroll) {
el_std_bitmap(text_chunky_buf, bitmap_base + (vc << 3) + rc, r);
memcpy(p, text_chunky_buf, 8*40);
} else
el_std_bitmap(p, bitmap_base + (vc << 3) + rc, r);
#endif
#else
el_std_bitmap(p, bitmap_base + (vc << 3) + rc, r);
#endif
break;
case 3: // Multicolor bitmap
#ifndef CAN_ACCESS_UNALIGNED
#ifdef ALIGNMENT_CHECK
el_mc_bitmap(use_p, bitmap_base + (vc << 3) + rc, r);
if (use_p != p)
memcpy(p, use_p, 8*40);
#else
if (x_scroll) {
el_mc_bitmap(text_chunky_buf, bitmap_base + (vc << 3) + rc, r);
memcpy(p, text_chunky_buf, 8*40);
} else
el_mc_bitmap(p, bitmap_base + (vc << 3) + rc, r);
#endif
#else
el_mc_bitmap(p, bitmap_base + (vc << 3) + rc, r);
#endif
break;
case 4: // ECM text
#ifndef CAN_ACCESS_UNALIGNED
#ifdef ALIGNMENT_CHECK
el_ecm_text(use_p, char_base + rc, r);
if (use_p != p)
memcpy(p, use_p, 8*40);
#else
if (x_scroll) {
el_ecm_text(text_chunky_buf, char_base + rc, r);
memcpy(p, text_chunky_buf, 8*40);
} else
el_ecm_text(p, char_base + rc, r);
#endif
#else
el_ecm_text(p, char_base + rc, r);
#endif
break;
default: // Invalid mode (all black)
memset(p, colors[0], 320);
memset(r, 0, 40);
break;
}
vc += 40;
} else { // Idle state graphics
switch (display_idx) {
case 0: // Standard text
case 1: // Multicolor text
case 4: // ECM text
#ifndef CAN_ACCESS_UNALIGNED
#ifdef ALIGNMENT_CHECK
el_std_idle(use_p, r);
if (use_p != p) {memcpy(p, use_p, 8*40);}
#else
if (x_scroll) {
el_std_idle(text_chunky_buf, r);
memcpy(p, text_chunky_buf, 8*40);
} else
el_std_idle(p, r);
#endif
#else
el_std_idle(p, r);
#endif
break;
case 3: // Multicolor bitmap
#ifndef CAN_ACCESS_UNALIGNED
#ifdef ALIGNMENT_CHECK
el_mc_idle(use_p, r);
if (use_p != p) {memcpy(p, use_p, 8*40);}
#else
if (x_scroll) {
el_mc_idle(text_chunky_buf, r);
memcpy(p, text_chunky_buf, 8*40);
} else
el_mc_idle(p, r);
#endif
#else
el_mc_idle(p, r);
#endif
break;
default: // Invalid mode (all black)
memset(p, colors[0], 320);
memset(r, 0, 40);
break;
}
}
// Draw sprites
if (sprite_on && ThePrefs.SpritesOn) {
// Clear sprite collision buffer
uint32 *lp = (uint32 *)spr_coll_buf - 1;
for (int i=0; i<DISPLAY_X/4; i++)
*++lp = 0;
el_sprites(chunky_ptr);
}
// Handle left/right border
uint32 *lp = (uint32 *)chunky_ptr - 1;
uint32 c = ec_color_long;
for (int i=0; i<COL40_XSTART/4; i++)
*++lp = c;
lp = (uint32 *)(chunky_ptr + COL40_XSTOP) - 1;
for (int i=0; i<(DISPLAY_X-COL40_XSTOP)/4; i++)
*++lp = c;
if (!border_40_col) {
c = ec_color;
p = chunky_ptr + COL40_XSTART - 1;
for (int i=0; i<COL38_XSTART-COL40_XSTART; i++)
*++p = c;
p = chunky_ptr + COL38_XSTOP - 1;
for (int i=0; i<COL40_XSTOP-COL38_XSTOP; i++)
*++p = c;
}
#if 0
if (is_bad_line) {
chunky_ptr[DISPLAY_X-2] = colors[7];
chunky_ptr[DISPLAY_X-3] = colors[7];
}
if (rc & 1) {
chunky_ptr[DISPLAY_X-4] = colors[1];
chunky_ptr[DISPLAY_X-5] = colors[1];
}
if (rc & 2) {
chunky_ptr[DISPLAY_X-6] = colors[1];
chunky_ptr[DISPLAY_X-7] = colors[1];
}
if (rc & 4) {
chunky_ptr[DISPLAY_X-8] = colors[1];
chunky_ptr[DISPLAY_X-9] = colors[1];
}
if (ctrl1 & 0x40) {
chunky_ptr[DISPLAY_X-10] = colors[5];
chunky_ptr[DISPLAY_X-11] = colors[5];
}
if (ctrl1 & 0x20) {
chunky_ptr[DISPLAY_X-12] = colors[3];
chunky_ptr[DISPLAY_X-13] = colors[3];
}
if (ctrl2 & 0x10) {
chunky_ptr[DISPLAY_X-14] = colors[2];
chunky_ptr[DISPLAY_X-15] = colors[2];
}
#endif
} else {
// Display border
uint32 *lp = (uint32 *)chunky_ptr - 1;
uint32 c = ec_color_long;
for (int i=0; i<DISPLAY_X/4; i++)
*++lp = c;
}
#ifdef __POWERPC__
// Copy temporary buffer to bitmap
fastcopy(chunky_line_start, (uint8 *)chunky_tmp);
#endif
// Increment pointer in chunky buffer
chunky_line_start += xmod;
// Increment row counter, go to idle state on overflow
if (rc == 7) {
display_state = false;
vc_base = vc;
} else
rc++;
if (raster >= FIRST_DMA_LINE-1 && raster <= LAST_DMA_LINE-1 && (((raster+1) & 7) == y_scroll) && bad_lines_enabled)
rc = 0;
}
VIC_nop:
// Skip this if all sprites are off
if (me | sprite_on)
cycles_left -= el_update_mc(raster);
return cycles_left;
}