/*************************************************************************************** * Genesis Plus * Video Display Processor (68k & Z80 CPU interface) * * Support for SG-1000, Master System (315-5124 & 315-5246), Game Gear & Mega Drive VDP * * Copyright (C) 1998, 1999, 2000, 2001, 2002, 2003 Charles Mac Donald (original code) * Copyright (C) 2007-2013 Eke-Eke (Genesis Plus GX) * * Redistribution and use of this code or any derivative works are permitted * provided that the following conditions are met: * * - Redistributions may not be sold, nor may they be used in a commercial * product or activity. * * - Redistributions that are modified from the original source must include the * complete source code, including the source code for all components used by a * binary built from the modified sources. However, as a special exception, the * source code distributed need not include anything that is normally distributed * (in either source or binary form) with the major components (compiler, kernel, * and so on) of the operating system on which the executable runs, unless that * component itself accompanies the executable. * * - Redistributions must reproduce the above copyright notice, this list of * conditions and the following disclaimer in the documentation and/or other * materials provided with the distribution. * * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" * AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE * ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE * LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE * POSSIBILITY OF SUCH DAMAGE. * ****************************************************************************************/ #include "shared.h" #include "hvc.h" /* Mark a pattern as modified */ #define MARK_BG_DIRTY(addr) \ { \ name = (addr >> 5) & 0x7FF; \ if(bg_name_dirty[name] == 0) \ { \ bg_name_list[bg_list_index++] = name; \ } \ bg_name_dirty[name] |= (1 << ((addr >> 2) & 7)); \ } /* VDP context */ uint8 sat[0x400]; /* Internal copy of sprite attribute table */ uint8 vram[0x10000]; /* Video RAM (64K x 8-bit) */ uint8 cram[0x80]; /* On-chip color RAM (64 x 9-bit) */ uint8 vsram[0x80]; /* On-chip vertical scroll RAM (40 x 11-bit) */ uint8 reg[0x20]; /* Internal VDP registers (23 x 8-bit) */ uint8 hint_pending; /* 0= Line interrupt is pending */ uint8 vint_pending; /* 1= Frame interrupt is pending */ uint16 status; /* VDP status flags */ uint32 dma_length; /* DMA remaining length */ /* Global variables */ uint16 ntab; /* Name table A base address */ uint16 ntbb; /* Name table B base address */ uint16 ntwb; /* Name table W base address */ uint16 satb; /* Sprite attribute table base address */ uint16 hscb; /* Horizontal scroll table base address */ uint8 bg_name_dirty[0x800]; /* 1= This pattern is dirty */ uint16 bg_name_list[0x800]; /* List of modified pattern indices */ uint16 bg_list_index; /* # of modified patterns in list */ uint8 hscroll_mask; /* Horizontal Scrolling line mask */ uint8 playfield_shift; /* Width of planes A, B (in bits) */ uint8 playfield_col_mask; /* Playfield column mask */ uint16 playfield_row_mask; /* Playfield row mask */ uint16 vscroll; /* Latched vertical scroll value */ uint8 odd_frame; /* 1: odd field, 0: even field */ uint8 im2_flag; /* 1= Interlace mode 2 is being used */ uint8 interlaced; /* 1: Interlaced mode 1 or 2 */ uint8 vdp_pal; /* 1: PAL , 0: NTSC (default) */ uint16 v_counter; /* Vertical counter */ uint16 vc_max; /* Vertical counter overflow value */ uint16 lines_per_frame; /* PAL: 313 lines, NTSC: 262 lines */ uint16 max_sprite_pixels; /* Max. sprites pixels per line (parsing & rendering) */ int32 fifo_write_cnt; /* VDP FIFO write count */ uint32 fifo_slots; /* VDP FIFO access slot count */ uint32 hvc_latch; /* latched HV counter */ const uint8 *hctab; /* pointer to H Counter table */ /* Function pointers */ void (*vdp_68k_data_w)(unsigned int data); void (*vdp_z80_data_w)(unsigned int data); unsigned int (*vdp_68k_data_r)(void); unsigned int (*vdp_z80_data_r)(void); /* Function prototypes */ static void vdp_68k_data_w_m4(unsigned int data); static void vdp_68k_data_w_m5(unsigned int data); static unsigned int vdp_68k_data_r_m4(void); static unsigned int vdp_68k_data_r_m5(void); static void vdp_z80_data_w_m4(unsigned int data); static void vdp_z80_data_w_m5(unsigned int data); static unsigned int vdp_z80_data_r_m4(void); static unsigned int vdp_z80_data_r_m5(void); static void vdp_z80_data_w_ms(unsigned int data); static void vdp_z80_data_w_gg(unsigned int data); static void vdp_z80_data_w_sg(unsigned int data); static void vdp_bus_w(unsigned int data); static void vdp_fifo_update(unsigned int cycles); static void vdp_reg_w(unsigned int r, unsigned int d, unsigned int cycles); static void vdp_dma_68k_ext(unsigned int length); static void vdp_dma_68k_ram(unsigned int length); static void vdp_dma_68k_io(unsigned int length); static void vdp_dma_copy(unsigned int length); static void vdp_dma_fill(unsigned int length); /* Tables that define the playfield layout */ static const uint8 hscroll_mask_table[] = { 0x00, 0x07, 0xF8, 0xFF }; static const uint8 shift_table[] = { 6, 7, 0, 8 }; static const uint8 col_mask_table[] = { 0x0F, 0x1F, 0x0F, 0x3F }; static const uint16 row_mask_table[] = { 0x0FF, 0x1FF, 0x2FF, 0x3FF }; static uint8 border; /* Border color index */ static uint8 pending; /* Pending write flag */ static uint8 code; /* Code register */ static uint8 dma_type; /* DMA mode */ static uint16 addr; /* Address register */ static uint16 addr_latch; /* Latched A15, A14 of address */ static uint16 sat_base_mask; /* Base bits of SAT */ static uint16 sat_addr_mask; /* Index bits of SAT */ static uint16 dma_src; /* DMA source address */ static uint32 dma_endCycles; /* 68k cycles to DMA end */ static int dmafill; /* DMA Fill pending flag */ static int cached_write; /* 2nd part of 32-bit CTRL port write (Genesis mode) or LSB of CRAM data (Game Gear mode) */ static uint16 fifo[4]; /* FIFO ring-buffer */ static int fifo_idx; /* FIFO write index */ static int fifo_byte_access; /* FIFO byte access flag */ static uint32 fifo_cycles; /* FIFO next access cycle */ /* set Z80 or 68k interrupt lines */ static void (*set_irq_line)(unsigned int level); static void (*set_irq_line_delay)(unsigned int level); /* Vertical counter overflow values (see hvc.h) */ static const uint16 vc_table[4][2] = { /* NTSC, PAL */ {0xDA , 0xF2}, /* Mode 4 (192 lines) */ {0xEA , 0x102}, /* Mode 5 (224 lines) */ {0xDA , 0xF2}, /* Mode 4 (192 lines) */ {0x106, 0x10A} /* Mode 5 (240 lines) */ }; /* DMA Timings (number of access slots per line) */ static const uint8 dma_timing[2][2] = { /* H32, H40 */ {16 , 18}, /* active display */ {167, 205} /* blank display */ }; /* DMA processing functions (set by VDP register 23 high nibble) */ static void (*const dma_func[16])(unsigned int length) = { /* 0x0-0x3 : DMA from 68k bus $000000-$7FFFFF (external area) */ vdp_dma_68k_ext,vdp_dma_68k_ext,vdp_dma_68k_ext,vdp_dma_68k_ext, /* 0x4-0x7 : DMA from 68k bus $800000-$FFFFFF (internal RAM & I/O) */ vdp_dma_68k_ram, vdp_dma_68k_io,vdp_dma_68k_ram,vdp_dma_68k_ram, /* 0x8-0xB : DMA Fill */ vdp_dma_fill,vdp_dma_fill,vdp_dma_fill,vdp_dma_fill, /* 0xC-0xF : DMA Copy */ vdp_dma_copy,vdp_dma_copy,vdp_dma_copy,vdp_dma_copy }; /*--------------------------------------------------------------------------*/ /* Init, reset, context functions */ /*--------------------------------------------------------------------------*/ void vdp_init(void) { /* PAL/NTSC timings */ lines_per_frame = vdp_pal ? 313: 262; /* CPU interrupt line(s)*/ if ((system_hw & SYSTEM_PBC) == SYSTEM_MD) { /* 68k cpu */ set_irq_line = m68k_set_irq; set_irq_line_delay = m68k_set_irq_delay; } else { /* Z80 cpu */ set_irq_line = z80_set_irq_line; set_irq_line_delay = z80_set_irq_line; } } void vdp_reset(void) { int i; memset ((char *) sat, 0, sizeof (sat)); memset ((char *) vram, 0, sizeof (vram)); memset ((char *) cram, 0, sizeof (cram)); memset ((char *) vsram, 0, sizeof (vsram)); memset ((char *) reg, 0, sizeof (reg)); addr = 0; addr_latch = 0; code = 0; pending = 0; border = 0; hint_pending = 0; vint_pending = 0; dmafill = 0; dma_src = 0; dma_type = 0; dma_length = 0; dma_endCycles = 0; odd_frame = 0; im2_flag = 0; interlaced = 0; fifo_write_cnt = 0; fifo_cycles = 0; fifo_slots = 0; fifo_idx = 0; cached_write = -1; fifo_byte_access = 1; ntab = 0; ntbb = 0; ntwb = 0; satb = 0; hscb = 0; vscroll = 0; hscroll_mask = 0x00; playfield_shift = 6; playfield_col_mask = 0x0F; playfield_row_mask = 0x0FF; sat_base_mask = 0xFE00; sat_addr_mask = 0x01FF; /* reset pattern cache changes */ bg_list_index = 0; memset ((char *) bg_name_dirty, 0, sizeof (bg_name_dirty)); memset ((char *) bg_name_list, 0, sizeof (bg_name_list)); /* default HVC */ hvc_latch = 0x10000; hctab = cycle2hc32; vc_max = vc_table[0][vdp_pal]; v_counter = lines_per_frame - 1; /* default Window clipping */ window_clip(0,0); /* reset VDP status (FIFO empty flag is set) */ if (system_hw & SYSTEM_MD) { status = vdp_pal | 0x200; } else { status = 0; } /* default display area */ bitmap.viewport.w = 256; bitmap.viewport.h = 192; bitmap.viewport.ow = 256; bitmap.viewport.oh = 192; /* default sprite pixel width */ max_sprite_pixels = 256; /* default overscan area */ if ((system_hw == SYSTEM_GG) && !config.gg_extra) { /* Display area reduced to 160x144 if overscan is disabled */ bitmap.viewport.x = (config.overscan & 2) ? 14 : -48; bitmap.viewport.y = (config.overscan & 1) ? (24 * (vdp_pal + 1)) : -24; } else { bitmap.viewport.x = (config.overscan & 2) * 7; bitmap.viewport.y = (config.overscan & 1) * 24 * (vdp_pal + 1); } /* default rendering mode */ update_bg_pattern_cache = update_bg_pattern_cache_m4; if (system_hw < SYSTEM_MD) { /* Mode 0 */ render_bg = render_bg_m0; render_obj = render_obj_tms; parse_satb = parse_satb_tms; } else { /* Mode 4 */ render_bg = render_bg_m4; render_obj = render_obj_m4; parse_satb = parse_satb_m4; } /* default 68k bus interface (Mega Drive VDP only) */ vdp_68k_data_w = vdp_68k_data_w_m4; vdp_68k_data_r = vdp_68k_data_r_m4; /* default Z80 bus interface */ switch (system_hw) { case SYSTEM_SG: { /* SG-1000 VDP (TMS99xx) */ vdp_z80_data_w = vdp_z80_data_w_sg; vdp_z80_data_r = vdp_z80_data_r_m4; break; } case SYSTEM_GG: { /* Game Gear VDP */ vdp_z80_data_w = vdp_z80_data_w_gg; vdp_z80_data_r = vdp_z80_data_r_m4; break; } case SYSTEM_MARKIII: case SYSTEM_SMS: case SYSTEM_SMS2: case SYSTEM_GGMS: { /* Master System or Game Gear (in MS compatibility mode) VDP */ vdp_z80_data_w = vdp_z80_data_w_ms; vdp_z80_data_r = vdp_z80_data_r_m4; break; } default: { /* Mega Drive VDP (in MS compatibility mode) */ vdp_z80_data_w = vdp_z80_data_w_m4; vdp_z80_data_r = vdp_z80_data_r_m4; break; } } /* SG-1000 specific */ if (system_hw == SYSTEM_SG) { /* 16k address decoding by default (Magical Kid Wiz) */ vdp_reg_w(1, 0x80, 0); /* no H-INT on TMS99xx */ vdp_reg_w(10, 0xFF, 0); } /* Master System specific */ else if ((system_hw & SYSTEM_SMS) && (!(config.bios & 1) || !(system_bios & SYSTEM_SMS))) { /* force registers initialization (only if Master System BIOS is disabled or not loaded) */ vdp_reg_w(0 , 0x36, 0); vdp_reg_w(1 , 0x80, 0); vdp_reg_w(2 , 0xFF, 0); vdp_reg_w(3 , 0xFF, 0); vdp_reg_w(4 , 0xFF, 0); vdp_reg_w(5 , 0xFF, 0); vdp_reg_w(6 , 0xFF, 0); vdp_reg_w(10, 0xFF, 0); /* Mode 4 */ render_bg = render_bg_m4; render_obj = render_obj_m4; parse_satb = parse_satb_m4; } /* Mega Drive specific */ else if (((system_hw == SYSTEM_MD) || (system_hw == SYSTEM_MCD)) && (config.bios & 1) && !(system_bios & SYSTEM_MD)) { /* force registers initialization (only if TMSS model is emulated and BOOT ROM is not loaded) */ vdp_reg_w(0 , 0x04, 0); vdp_reg_w(1 , 0x04, 0); vdp_reg_w(10, 0xFF, 0); vdp_reg_w(12, 0x81, 0); vdp_reg_w(15, 0x02, 0); } /* reset color palette */ for(i = 0; i < 0x20; i ++) { color_update_m4(i, 0x00); } color_update_m4(0x40, 0x00); } int vdp_context_save(uint8 *state) { int bufferptr = 0; save_param(sat, sizeof(sat)); save_param(vram, sizeof(vram)); save_param(cram, sizeof(cram)); save_param(vsram, sizeof(vsram)); save_param(reg, sizeof(reg)); save_param(&addr, sizeof(addr)); save_param(&addr_latch, sizeof(addr_latch)); save_param(&code, sizeof(code)); save_param(&pending, sizeof(pending)); save_param(&status, sizeof(status)); save_param(&dmafill, sizeof(dmafill)); save_param(&fifo_idx, sizeof(fifo_idx)); save_param(&fifo, sizeof(fifo)); save_param(&hint_pending, sizeof(hint_pending)); save_param(&vint_pending, sizeof(vint_pending)); save_param(&dma_length, sizeof(dma_length)); save_param(&dma_type, sizeof(dma_type)); save_param(&dma_src, sizeof(dma_src)); save_param(&cached_write, sizeof(cached_write)); return bufferptr; } int vdp_context_load(uint8 *state, uint8 version) { int i, bufferptr = 0; uint8 temp_reg[0x20]; load_param(sat, sizeof(sat)); load_param(vram, sizeof(vram)); load_param(cram, sizeof(cram)); load_param(vsram, sizeof(vsram)); load_param(temp_reg, sizeof(temp_reg)); /* restore VDP registers */ if (system_hw < SYSTEM_MD) { if (system_hw > SYSTEM_SG) { for (i=0;i<0x10;i++) { pending = 1; addr_latch = temp_reg[i]; vdp_sms_ctrl_w(0x80 | i); } } else { for (i=0;i<0x08;i++) { pending = 1; addr_latch = temp_reg[i]; vdp_tms_ctrl_w(0x80 | i); } } } else { for (i=0;i<0x20;i++) { vdp_reg_w(i, temp_reg[i], 0); } } load_param(&addr, sizeof(addr)); load_param(&addr_latch, sizeof(addr_latch)); load_param(&code, sizeof(code)); load_param(&pending, sizeof(pending)); load_param(&status, sizeof(status)); /* 1.7.1 state compatibility */ if (version < 0x35) { uint16 temp; load_param(&temp, 2); dmafill = temp >> 8; temp &= 0xff; fifo_idx = 0; fifo[0] = fifo[1] = fifo[2] = fifo[3] = (temp << 8) | temp; } else { load_param(&dmafill, sizeof(dmafill)); load_param(&fifo_idx, sizeof(fifo_idx)); load_param(&fifo, sizeof(fifo)); } load_param(&hint_pending, sizeof(hint_pending)); load_param(&vint_pending, sizeof(vint_pending)); load_param(&dma_length, sizeof(dma_length)); load_param(&dma_type, sizeof(dma_type)); load_param(&dma_src, sizeof(dma_src)); load_param(&cached_write, sizeof(cached_write)); /* restore FIFO byte access flag */ fifo_byte_access = ((code & 0x0F) < 0x03); /* restore current NTSC/PAL mode */ if (system_hw & SYSTEM_MD) { status = (status & ~1) | vdp_pal; } if (reg[1] & 0x04) { /* Mode 5 */ bg_list_index = 0x800; /* reinitialize palette */ color_update_m5(0, *(uint16 *)&cram[border << 1]); for(i = 1; i < 0x40; i++) { color_update_m5(i, *(uint16 *)&cram[i << 1]); } } else { /* Modes 0,1,2,3,4 */ bg_list_index = 0x200; /* reinitialize palette */ for(i = 0; i < 0x20; i ++) { color_update_m4(i, *(uint16 *)&cram[i << 1]); } color_update_m4(0x40, *(uint16 *)&cram[(0x10 | (border & 0x0F)) << 1]); } /* invalidate cache */ for (i=0;i VDP 32-cell Active 16 Blanking 167 40-cell Active 18 Blanking 205 VRAM Fill 32-cell Active 15 Blanking 166 40-cell Active 17 Blanking 204 VRAM Copy 32-cell Active 8 Blanking 83 40-cell Active 9 Blanking 102 'Active' is the active display period, 'Blanking' is either the vertical blanking period or when the display is forcibly blanked via register #1. The above transfer counts are all in bytes, unless the destination is CRAM or VSRAM for a 68K > VDP transfer, in which case it is in words. */ unsigned int rate = dma_timing[(status & 8) || !(reg[1] & 0x40)][reg[12] & 1]; /* Adjust for 68k bus DMA to VRAM (one word = 2 access) or DMA Copy (one read + one write = 2 access) */ rate = rate >> (dma_type & 1); /* Remaining DMA cycles */ if (status & 8) { /* Process DMA until the end of VBLANK */ /* NOTE: DMA timings can not change during VBLANK because active display width cannot be modified. */ /* Indeed, writing VDP registers during DMA is either impossible (when doing DMA from 68k bus, CPU */ /* is locked) or will abort DMA operation (in case of DMA Fill or Copy). */ dma_cycles = (lines_per_frame * MCYCLES_PER_LINE) - cycles; } else { /* Process DMA until the end of current line */ dma_cycles = (mcycles_vdp + MCYCLES_PER_LINE) - cycles; } /* Remaining DMA bytes for that line */ dma_bytes = (dma_cycles * rate) / MCYCLES_PER_LINE; #ifdef LOGVDP error("[%d(%d)][%d(%d)] DMA type %d (%d access/line)(%d cycles left)-> %d access (%d remaining) (%x)\n", v_counter, m68k.cycles/MCYCLES_PER_LINE, m68k.cycles, m68k.cycles%MCYCLES_PER_LINE,dma_type, rate, dma_cycles, dma_bytes, dma_length, m68k_get_reg(M68K_REG_PC)); #endif /* Check if DMA can be finished before the end of current line */ if (dma_length < dma_bytes) { /* Adjust remaining DMA bytes */ dma_bytes = dma_length; dma_cycles = (dma_bytes * MCYCLES_PER_LINE) / rate; } /* Update DMA timings */ if (dma_type < 2) { /* 68K is frozen during DMA from 68k bus */ m68k.cycles = cycles + dma_cycles; #ifdef LOGVDP error("-->CPU frozen for %d cycles\n", dma_cycles); #endif } else { /* Set DMA Busy flag */ status |= 0x02; /* 68K is still running, set DMA end cycle */ dma_endCycles = cycles + dma_cycles; #ifdef LOGVDP error("-->DMA ends in %d cycles\n", dma_cycles); #endif } /* Process DMA */ if (dma_bytes > 0) { /* Update DMA length */ dma_length -= dma_bytes; /* Process DMA operation */ dma_func[reg[23] >> 4](dma_bytes); /* Check if DMA is finished */ if (!dma_length) { /* DMA source address registers are incremented during DMA (even DMA Fill) */ uint16 end = reg[21] + (reg[22] << 8) + reg[19] + (reg[20] << 8); reg[21] = end & 0xff; reg[22] = end >> 8; /* DMA length registers are decremented during DMA */ reg[19] = reg[20] = 0; /* perform cached write, if any */ if (cached_write >= 0) { vdp_68k_ctrl_w(cached_write); cached_write = -1; } } } } /*--------------------------------------------------------------------------*/ /* Control port access functions */ /*--------------------------------------------------------------------------*/ void vdp_68k_ctrl_w(unsigned int data) { /* Check pending flag */ if (pending == 0) { /* A single long word write instruction could have started DMA with the first word */ if (dma_length) { /* 68k is frozen during 68k bus DMA */ /* Second word should be written after DMA completion */ /* See Formula One & Kawasaki Superbike Challenge */ if (dma_type < 2) { /* Latch second control word for later */ cached_write = data; return; } } /* Check CD0-CD1 bits */ if ((data & 0xC000) == 0x8000) { /* VDP register write */ vdp_reg_w((data >> 8) & 0x1F, data & 0xFF, m68k.cycles); } else { /* Set pending flag (Mode 5 only) */ pending = reg[1] & 4; } /* Update address and code registers */ addr = addr_latch | (data & 0x3FFF); code = ((code & 0x3C) | ((data >> 14) & 0x03)); } else { /* Clear pending flag */ pending = 0; /* Save address bits A15 and A14 */ addr_latch = (data & 3) << 14; /* Update address and code registers */ addr = addr_latch | (addr & 0x3FFF); code = ((code & 0x03) | ((data >> 2) & 0x3C)); /* Detect DMA operation (CD5 bit set) */ if (code & 0x20) { /* DMA must be enabled */ if (reg[1] & 0x10) { /* DMA type */ switch (reg[23] >> 6) { case 2: { /* DMA Fill */ dma_type = 2; /* DMA is pending until next DATA port write */ dmafill = 1; /* Set DMA Busy flag */ status |= 0x02; /* DMA end cycle is not initialized yet (this prevents DMA Busy flag from being cleared on VDP status read) */ dma_endCycles = 0xffffffff; break; } case 3: { /* DMA Copy */ dma_type = 3; /* DMA length */ dma_length = (reg[20] << 8) | reg[19]; /* Zero DMA length (pre-decrementing counter) */ if (!dma_length) { dma_length = 0x10000; } /* DMA source address */ dma_src = (reg[22] << 8) | reg[21]; /* Trigger DMA */ vdp_dma_update(m68k.cycles); break; } default: { /* DMA from 68k bus */ dma_type = (code & 0x06) ? 0 : 1; /* DMA length */ dma_length = (reg[20] << 8) | reg[19]; /* Zero DMA length (pre-decrementing counter) */ if (!dma_length) { dma_length = 0x10000; } /* DMA source address */ dma_src = (reg[22] << 8) | reg[21]; /* Transfer from SVP ROM/RAM ($000000-$3fffff) or CD Word-RAM ($200000-$3fffff/$600000-$7fffff) */ if (((system_hw == SYSTEM_MCD) && ((reg[23] & 0x70) == ((scd.cartridge.boot >> 1) + 0x10))) || (svp && !(reg[23] & 0x60))) { /* source data is available with one cycle delay, i.e first word written by VDP is */ /* previous data being held on 68k bus at that time, then source words are written */ /* normally to VDP RAM, with only last source word being ignored */ addr += reg[15]; dma_length--; } /* Trigger DMA */ vdp_dma_update(m68k.cycles); break; } } } } } /* FIFO emulation (Chaos Engine/Soldier of Fortune, Double Clutch, Sol Deace) -------------------------------------------------------------------------- Each VRAM access is byte wide, so one VRAM write (word) need twice cycles. Note: Invalid code 0x02 (register write) apparently behaves the same as VRAM access, although no data is written in this case (fixes Clue menu) */ fifo_byte_access = ((code & 0x0F) <= 0x02); } /* Mega Drive VDP control port specific (MS compatibility mode) */ void vdp_z80_ctrl_w(unsigned int data) { switch (pending) { case 0: { /* Latch LSB */ addr_latch = data; /* Set LSB pending flag */ pending = 1; return; } case 1: { /* Update address and code registers */ addr = (addr & 0xC000) | ((data & 0x3F) << 8) | addr_latch ; code = ((code & 0x3C) | ((data >> 6) & 0x03)); if ((code & 0x03) == 0x02) { /* VDP register write */ vdp_reg_w(data & 0x1F, addr_latch, Z80.cycles); /* Clear pending flag */ pending = 0; return; } /* Set Mode 5 pending flag */ pending = (reg[1] & 4) >> 1; if (!pending && !(code & 0x03)) { /* Process VRAM read */ fifo[0] = vram[addr & 0x3FFF]; /* Increment address register */ addr += (reg[15] + 1); } return; } case 2: { /* Latch LSB */ addr_latch = data; /* Set LSB pending flag */ pending = 3; return; } case 3: { /* Clear pending flag */ pending = 0; /* Update address and code registers */ addr = ((addr_latch & 3) << 14) | (addr & 0x3FFF); code = ((code & 0x03) | ((addr_latch >> 2) & 0x3C)); /* Detect DMA operation (CD5 bit set) */ if (code & 0x20) { /* DMA should be enabled */ if (reg[1] & 0x10) { /* DMA type */ switch (reg[23] >> 6) { case 2: { /* DMA Fill will be triggered by next write to DATA port */ dmafill = 1; /* Set DMA Busy flag */ status |= 0x02; /* DMA end cycle is not initialized yet (this prevents DMA Busy flag from being cleared on VDP status read) */ dma_endCycles = 0xffffffff; break; } case 3: { /* DMA copy */ dma_type = 3; /* DMA length */ dma_length = (reg[20] << 8) | reg[19]; /* Zero DMA length (pre-decrementing counter) */ if (!dma_length) { dma_length = 0x10000; } /* DMA source address */ dma_src = (reg[22] << 8) | reg[21]; /* Trigger DMA */ vdp_dma_update(Z80.cycles); break; } default: { /* DMA from 68k bus does not work when Z80 is in control */ break; } } } } } return; } } /* Master System & Game Gear VDP control port specific */ void vdp_sms_ctrl_w(unsigned int data) { if(pending == 0) { /* Update address register LSB */ addr = (addr & 0x3F00) | (data & 0xFF); /* Latch LSB */ addr_latch = data; /* Set LSB pending flag */ pending = 1; } else { /* Update address and code registers */ code = (data >> 6) & 3; addr = (data << 8 | addr_latch) & 0x3FFF; /* Clear pending flag */ pending = 0; if (code == 0) { /* Process VRAM read */ fifo[0] = vram[addr & 0x3FFF]; /* Increment address register */ addr = (addr + 1) & 0x3FFF; return; } if (code == 2) { /* Save current VDP mode */ int mode, prev = (reg[0] & 0x06) | (reg[1] & 0x18); /* Write VDP register 0-15 */ vdp_reg_w(data & 0x0F, addr_latch, Z80.cycles); /* Check VDP mode changes */ mode = (reg[0] & 0x06) | (reg[1] & 0x18); prev ^= mode; if (prev) { /* Check for extended modes */ if (system_hw > SYSTEM_SMS) { int height; if (mode == 0x0E) /* M1=0,M2=1,M3=1,M4=1 */ { /* Mode 4 extended (240 lines) */ height = 240; /* Update vertical counter max value */ vc_max = vc_table[3][vdp_pal]; } else if (mode == 0x16) /* M1=1,M2=1,M3=0,M4=1 */ { /* Mode 4 extended (224 lines) */ height = 224; /* Update vertical counter max value */ vc_max = vc_table[1][vdp_pal]; } else { /* Mode 4 default (224 lines) */ height = 192; /* Default vertical counter max value */ vc_max = vc_table[0][vdp_pal]; } if (height != bitmap.viewport.h) { if (status & 8) { /* viewport changes should be applied on next frame */ bitmap.viewport.changed |= 2; } else { /* update active display */ bitmap.viewport.h = height; /* update vertical overscan */ if (config.overscan & 1) { bitmap.viewport.y = (240 + 48*vdp_pal - height) >> 1; } else { if ((system_hw == SYSTEM_GG) && !config.gg_extra) { /* Display area reduced to 160x144 */ bitmap.viewport.y = (144 - height) / 2; } else { bitmap.viewport.y = 0; } } } } } /* Rendering mode */ switch (mode) { case 0x00: /* Graphics I */ { render_bg = render_bg_m0; break; } case 0x10: /* Text */ { render_bg = render_bg_m1; break; } case 0x02: /* Graphics II */ { render_bg = render_bg_m2; break; } case 0x12: /* Text (Extended PG) */ { render_bg = render_bg_m1x; break; } case 0x08: /* Multicolor */ { render_bg = render_bg_m3; break; } case 0x18: /* Invalid (1+3) */ { render_bg = render_bg_inv; break; } case 0x0A: /* Multicolor (Extended PG) */ { render_bg = render_bg_m3x; break; } case 0x1A: /* Invalid (1+2+3) */ { render_bg = render_bg_inv; break; } default: /* Mode 4 */ { render_bg = render_bg_m4; break; } } /* Mode switching */ if (prev & 0x04) { int i; if (mode & 0x04) { /* Mode 4 sprites */ parse_satb = parse_satb_m4; render_obj = render_obj_m4; /* force BG cache update*/ bg_list_index = 0x200; } else { /* TMS-mode sprites */ parse_satb = parse_satb_tms; render_obj = render_obj_tms; /* BG cache is not used */ bg_list_index = 0; } /* reinitialize palette */ for(i = 0; i < 0x20; i ++) { color_update_m4(i, *(uint16 *)&cram[i << 1]); } color_update_m4(0x40, *(uint16 *)&cram[(0x10 | (border & 0x0F)) << 1]); } } } } } /* SG-1000 VDP (TMS99xx) control port specific */ void vdp_tms_ctrl_w(unsigned int data) { if(pending == 0) { /* Latch LSB */ addr_latch = data; /* Set LSB pending flag */ pending = 1; } else { /* Update address and code registers */ code = (data >> 6) & 3; addr = (data << 8 | addr_latch) & 0x3FFF; /* Clear pending flag */ pending = 0; if (code == 0) { /* Process VRAM read */ fifo[0] = vram[addr & 0x3FFF]; /* Increment address register */ addr = (addr + 1) & 0x3FFF; return; } if (code & 2) { /* VDP register index (0-7) */ data &= 0x07; /* Write VDP register */ vdp_reg_w(data, addr_latch, Z80.cycles); /* Check VDP mode changes */ if (data < 2) { int mode = (reg[0] & 0x02) | (reg[1] & 0x18); /* Rendering mode */ switch (mode) { case 0x00: /* Graphics I */ { render_bg = render_bg_m0; break; } case 0x10: /* Text */ { render_bg = render_bg_m1; break; } case 0x02: /* Graphics II */ { render_bg = render_bg_m2; break; } case 0x12: /* Text (Extended PG) */ { render_bg = render_bg_m1x; break; } case 0x08: /* Multicolor */ { render_bg = render_bg_m3; break; } case 0x18: /* Invalid (1+3) */ { render_bg = render_bg_inv; break; } case 0x0A: /* Multicolor (Extended PG) */ { render_bg = render_bg_m3x; break; } case 0x1A: /* Invalid (1+2+3) */ { render_bg = render_bg_inv; break; } } } } } } /* * Status register * * Bits * 0 NTSC(0)/PAL(1) * 1 DMA Busy * 2 During HBlank * 3 During VBlank * 4 0:1 even:odd field (interlaced modes only) * 5 Sprite collision * 6 Too many sprites per line * 7 v interrupt occurred * 8 Write FIFO full * 9 Write FIFO empty * 10 - 15 Open Bus */ unsigned int vdp_68k_ctrl_r(unsigned int cycles) { unsigned int temp; /* Update FIFO status flags if not empty */ if (fifo_write_cnt) { vdp_fifo_update(cycles); } /* Check if DMA Busy flag is set */ if (status & 2) { /* Check if DMA is finished */ if (!dma_length && (cycles >= dma_endCycles)) { /* Clear DMA Busy flag */ status &= 0xFFFD; } } /* Return VDP status */ temp = status; /* Clear pending flag */ pending = 0; /* Clear SOVR & SCOL flags */ status &= 0xFF9F; /* Display OFF: VBLANK flag is set */ if (!(reg[1] & 0x40)) { temp |= 0x08; } /* HBLANK flag (Sonic 3 and Sonic 2 "VS Modes", Lemmings 2, Mega Turrican, V.R Troopers, Gouketsuji Ichizoku,...) */ /* NB: this is not 100% accurate and need to be verified on real hardware */ if ((cycles % MCYCLES_PER_LINE) < 588) { temp |= 0x04; } #ifdef LOGVDP error("[%d(%d)][%d(%d)] VDP 68k status read -> 0x%x (0x%x) (%x)\n", v_counter, cycles/MCYCLES_PER_LINE-1, cycles, cycles%MCYCLES_PER_LINE, temp, status, m68k_get_reg(M68K_REG_PC)); #endif return (temp); } unsigned int vdp_z80_ctrl_r(unsigned int cycles) { unsigned int temp; /* Cycle-accurate SOVR & VINT flags */ int line = (lines_per_frame + (cycles / MCYCLES_PER_LINE) - 1) % lines_per_frame; /* Check if DMA busy flag is set (Mega Drive VDP specific) */ if (status & 2) { /* Check if DMA is finished */ if (!dma_length && (cycles >= dma_endCycles)) { /* Clear DMA Busy flag */ status &= 0xFD; } } /* Check if we are already on next line */ if (line > v_counter) { v_counter = line; if (line == (bitmap.viewport.h + 1)) { /* set VINT flag (immediately cleared after) */ status |= 0x80; } else if ((line >= 0) && (line < bitmap.viewport.h) && !(work_ram[0x1ffb] & cart.special)) { /* render next line to check sprites overflow & collision */ render_line(line); } } /* Return VDP status */ temp = status; /* Clear pending flag */ pending = 0; /* Clear VINT, SOVR & SCOL flags */ status &= 0xFF1F; /* Mega Drive VDP specific */ if (system_hw & SYSTEM_MD) { /* Display OFF: VBLANK flag is set */ if (!(reg[1] & 0x40)) { temp |= 0x08; } /* HBLANK flag */ if ((cycles % MCYCLES_PER_LINE) < 588) { temp |= 0x04; } } else if (reg[0] & 0x04) { /* Mode 4 unused bits (fixes PGA Tour Golf) */ temp |= 0x1F; } /* Cycle-accurate SCOL flag */ if ((temp & 0x20) && (line == (spr_col >> 8))) { if (system_hw & SYSTEM_MD) { /* COL flag is set at HCount 0xFF on MD */ if ((cycles % MCYCLES_PER_LINE) < 105) { status |= 0x20; temp &= ~0x20; } } else { /* COL flag is set at the pixel it occurs */ uint8 hc = hctab[(cycles + SMS_CYCLE_OFFSET + 15) % MCYCLES_PER_LINE]; if ((hc < (spr_col & 0xff)) || (hc > 0xf3)) { status |= 0x20; temp &= ~0x20; } } } /* Clear HINT & VINT pending flags */ hint_pending = vint_pending = 0; /* Clear Z80 interrupt */ Z80.irq_state = CLEAR_LINE; #ifdef LOGVDP error("[%d(%d)][%d(%d)] VDP Z80 status read -> 0x%x (0x%x) (%x)\n", v_counter, cycles/MCYCLES_PER_LINE-1, cycles, cycles%MCYCLES_PER_LINE, temp, status, Z80.pc.w.l); #endif return (temp); } /*--------------------------------------------------------------------------*/ /* HV Counters */ /*--------------------------------------------------------------------------*/ unsigned int vdp_hvc_r(unsigned int cycles) { int vc; unsigned int data = hvc_latch; /* Check if HVC latch is enabled */ if (data) { /* Mode 5: HV-counters are frozen (cf. lightgun games, Sunset Riders logo) */ if (reg[1] & 0x04) { #ifdef LOGVDP error("[%d(%d)][%d(%d)] HVC latch read -> 0x%x (%x)\n", v_counter, (cycles/MCYCLES_PER_LINE-1)%lines_per_frame, cycles, cycles%MCYCLES_PER_LINE, data & 0xffff, m68k_get_reg(M68K_REG_PC)); #endif /* return latched HVC value */ return (data & 0xffff); } else { /* Mode 4: by default, V-counter runs normally & H counter is frozen */ data &= 0xff; } } else { /* Cycle-accurate H-Counter (Striker, Mickey Mania, Skitchin, Road Rash I,II,III, Sonic 3D Blast...) */ data = hctab[cycles % MCYCLES_PER_LINE]; } /* Cycle-accurate V-Counter (cycle counter starts from line -1) */ vc = (cycles / MCYCLES_PER_LINE) - 1; /* V-Counter overflow */ if (vc > vc_max) { vc -= lines_per_frame; } /* Interlaced modes */ if (interlaced) { /* Interlace mode 2 (Sonic the Hedgehog 2, Combat Cars) */ vc <<= im2_flag; /* Replace bit 0 with bit 8 */ vc = (vc & ~1) | ((vc >> 8) & 1); } /* return H-Counter in LSB & V-Counter in MSB */ data |= ((vc & 0xff) << 8); #ifdef LOGVDP error("[%d(%d)][%d(%d)] HVC read -> 0x%x (%x)\n", v_counter, (cycles/MCYCLES_PER_LINE-1)%lines_per_frame, cycles, cycles%MCYCLES_PER_LINE, data, m68k_get_reg(M68K_REG_PC)); #endif return (data); } /*--------------------------------------------------------------------------*/ /* Test registers */ /*--------------------------------------------------------------------------*/ void vdp_test_w(unsigned int data) { #ifdef LOGERROR error("Unused VDP Write 0x%x (%08x)\n", data, m68k_get_reg(M68K_REG_PC)); #endif } /*--------------------------------------------------------------------------*/ /* 68k interrupt handler (TODO: check how interrupts are handled in Mode 4) */ /*--------------------------------------------------------------------------*/ int vdp_68k_irq_ack(int int_level) { #ifdef LOGVDP error("[%d(%d)][%d(%d)] INT Level %d ack (%x)\n", v_counter, m68k.cycles/MCYCLES_PER_LINE-1, m68k.cycles, m68k.cycles%MCYCLES_PER_LINE,int_level, m68k_get_reg(M68K_REG_PC)); #endif /* VINT has higher priority (Fatal Rewind) */ if (vint_pending & reg[1]) { #ifdef LOGVDP error("---> VINT cleared\n"); #endif /* Clear VINT pending flag */ vint_pending = 0; status &= ~0x80; /* Update IRQ status */ if (hint_pending & reg[0]) { m68k_set_irq(4); } else { m68k_set_irq(0); } } else { #ifdef LOGVDP error("---> HINT cleared\n"); #endif /* Clear HINT pending flag */ hint_pending = 0; /* Update IRQ status */ m68k_set_irq(0); } return M68K_INT_ACK_AUTOVECTOR; } /*--------------------------------------------------------------------------*/ /* VDP registers update function */ /*--------------------------------------------------------------------------*/ static void vdp_reg_w(unsigned int r, unsigned int d, unsigned int cycles) { #ifdef LOGVDP error("[%d(%d)][%d(%d)] VDP register %d write -> 0x%x (%x)\n", v_counter, cycles/MCYCLES_PER_LINE-1, cycles, cycles%MCYCLES_PER_LINE, r, d, m68k_get_reg(M68K_REG_PC)); #endif /* VDP registers #11 to #23 cannot be updated in Mode 4 (Captain Planet & Avengers, Bass Master Classic Pro Edition) */ if (!(reg[1] & 4) && (r > 10)) { return; } switch(r) { case 0: /* CTRL #1 */ { /* Look for changed bits */ r = d ^ reg[0]; reg[0] = d; /* Line Interrupt */ if ((r & 0x10) && hint_pending) { /* Update IRQ status */ if (vint_pending & reg[1]) { set_irq_line(6); } else if (d & 0x10) { set_irq_line_delay(4); } else { set_irq_line(0); } } /* Palette selection */ if (r & 0x04) { /* Mega Drive VDP only */ if (system_hw & SYSTEM_MD) { /* Reset color palette */ int i; if (reg[1] & 0x04) { /* Mode 5 */ color_update_m5(0x00, *(uint16 *)&cram[border << 1]); for (i = 1; i < 0x40; i++) { color_update_m5(i, *(uint16 *)&cram[i << 1]); } } else { /* Mode 4 */ for (i = 0; i < 0x20; i++) { color_update_m4(i, *(uint16 *)&cram[i << 1]); } color_update_m4(0x40, *(uint16 *)&cram[(0x10 | (border & 0x0F)) << 1]); } } } /* HVC latch (Sunset Riders, Lightgun games) */ if (r & 0x02) { /* Mega Drive VDP only */ if (system_hw & SYSTEM_MD) { /* Mode 5 only */ if (reg[1] & 0x04) { if (d & 0x02) { /* Latch current HVC */ hvc_latch = vdp_hvc_r(cycles) | 0x10000; } else { /* Free-running HVC */ hvc_latch = 0; } } } } break; } case 1: /* CTRL #2 */ { /* Look for changed bits */ r = d ^ reg[1]; reg[1] = d; /* Display status (modified during active display) */ if ((r & 0x40) && (v_counter < bitmap.viewport.h)) { /* Cycle offset vs HBLANK */ int offset = cycles - mcycles_vdp; if (offset <= 860) { /* Sprite rendering is limited if display was disabled during HBLANK (Mickey Mania 3d level, Overdrive Demo) */ if (d & 0x40) { /* NB: This is not 100% accurate. On real hardware, the maximal number of rendered sprites pixels */ /* for the current line (normally 256 or 320 pixels) but also the maximal number of pre-processed */ /* sprites for the next line (normally 64 or 80 sprites) are both reduced depending on the amount */ /* of cycles spent with display disabled. Here we only reduce them by a fixed amount when display */ /* has been reenabled after a specific point within HBLANK. */ if (offset > 360) { max_sprite_pixels = 128; } } /* Redraw entire line (Legend of Galahad, Lemmings 2, Formula One, Kawasaki Super Bike, Deadly Moves,...) */ render_line(v_counter); /* Restore default */ max_sprite_pixels = 256 + ((reg[12] & 1) << 6); } else if (system_hw & SYSTEM_MD) { /* Active pixel offset */ if (reg[12] & 1) { /* dot clock = MCLK / 8 */ offset = ((offset - 860) / 8) + 16; } else { /* dot clock = MCLK / 10 */ offset = ((offset - 860) / 10) + 16; } /* Line is partially blanked (Nigel Mansell's World Championship Racing , Ren & Stimpy Show, ...) */ if (offset < bitmap.viewport.w) { if (d & 0x40) { render_line(v_counter); blank_line(v_counter, 0, offset); } else { blank_line(v_counter, offset, bitmap.viewport.w - offset); } } } } /* Frame Interrupt */ if ((r & 0x20) && vint_pending) { /* Update IRQ status */ if (d & 0x20) { set_irq_line_delay(6); } else if (hint_pending & reg[0]) { set_irq_line(4); } else { set_irq_line(0); } } /* Active display height */ if (r & 0x08) { /* Mega Drive VDP only */ if (system_hw & SYSTEM_MD) { /* Mode 5 only */ if (d & 0x04) { /* Changes should be applied on next frame */ bitmap.viewport.changed |= 2; /* Update vertical counter max value */ vc_max = vc_table[(d >> 2) & 3][vdp_pal]; } } } /* Rendering mode */ if (r & 0x04) { /* Mega Drive VDP only */ if (system_hw & SYSTEM_MD) { int i; if (d & 0x04) { /* Mode 5 rendering */ parse_satb = parse_satb_m5; update_bg_pattern_cache = update_bg_pattern_cache_m5; if (im2_flag) { render_bg = (reg[11] & 0x04) ? render_bg_m5_im2_vs : render_bg_m5_im2; render_obj = (reg[12] & 0x08) ? render_obj_m5_im2_ste : render_obj_m5_im2; } else { render_bg = (reg[11] & 0x04) ? render_bg_m5_vs : render_bg_m5; render_obj = (reg[12] & 0x08) ? render_obj_m5_ste : render_obj_m5; } /* Reset color palette */ color_update_m5(0x00, *(uint16 *)&cram[border << 1]); for (i = 1; i < 0x40; i++) { color_update_m5(i, *(uint16 *)&cram[i << 1]); } /* Mode 5 bus access */ vdp_68k_data_w = vdp_68k_data_w_m5; vdp_z80_data_w = vdp_z80_data_w_m5; vdp_68k_data_r = vdp_68k_data_r_m5; vdp_z80_data_r = vdp_z80_data_r_m5; /* Change display height */ if (status & 8) { /* viewport changes should be applied on next frame */ bitmap.viewport.changed |= 2; } else { /* Update current frame active display height */ bitmap.viewport.h = 224 + ((d & 8) << 1); bitmap.viewport.y = (config.overscan & 1) * (8 - (d & 8) + 24*vdp_pal); } /* Clear HVC latched value */ hvc_latch = 0; /* Check if HVC latch bit is set */ if (reg[0] & 0x02) { /* Latch current HVC */ hvc_latch = vdp_hvc_r(cycles) | 0x10000; } /* max tiles to invalidate */ bg_list_index = 0x800; } else { /* Mode 4 rendering */ parse_satb = parse_satb_m4; update_bg_pattern_cache = update_bg_pattern_cache_m4; render_bg = render_bg_m4; render_obj = render_obj_m4; /* Reset color palette */ for (i = 0; i < 0x20; i++) { color_update_m4(i, *(uint16 *)&cram[i << 1]); } color_update_m4(0x40, *(uint16 *)&cram[(0x10 | (border & 0x0F)) << 1]); /* Mode 4 bus access */ vdp_68k_data_w = vdp_68k_data_w_m4; vdp_z80_data_w = vdp_z80_data_w_m4; vdp_68k_data_r = vdp_68k_data_r_m4; vdp_z80_data_r = vdp_z80_data_r_m4; if (status & 8) { /* viewport changes should be applied on next frame */ bitmap.viewport.changed |= 2; } else { /* Update current frame active display */ bitmap.viewport.h = 192; bitmap.viewport.y = (config.overscan & 1) * 24 * (vdp_pal + 1); } /* Latch current HVC */ hvc_latch = vdp_hvc_r(cycles) | 0x10000; /* max tiles to invalidate */ bg_list_index = 0x200; } /* Invalidate pattern cache */ for (i=0;i> 2) & 3][vdp_pal]; } else { /* No effect (cleared to avoid mode 5 detection elsewhere) */ reg[1] &= ~0x04; } } break; } case 2: /* Plane A Name Table Base */ { reg[2] = d; ntab = (d << 10) & 0xE000; /* Plane A Name Table Base changed during HBLANK */ if ((v_counter < bitmap.viewport.h) && (reg[1] & 0x40) && (cycles <= (mcycles_vdp + 860))) { /* render entire line */ render_line(v_counter); } break; } case 3: /* Window Plane Name Table Base */ { reg[3] = d; if (reg[12] & 0x01) { ntwb = (d << 10) & 0xF000; } else { ntwb = (d << 10) & 0xF800; } /* Window Plane Name Table Base changed during HBLANK */ if ((v_counter < bitmap.viewport.h) && (reg[1] & 0x40) && (cycles <= (mcycles_vdp + 860))) { /* render entire line */ render_line(v_counter); } break; } case 4: /* Plane B Name Table Base */ { reg[4] = d; ntbb = (d << 13) & 0xE000; /* Plane B Name Table Base changed during HBLANK (Adventures of Batman & Robin) */ if ((v_counter < bitmap.viewport.h) && (reg[1] & 0x40) && (cycles <= (mcycles_vdp + 860))) { /* render entire line */ render_line(v_counter); } break; } case 5: /* Sprite Attribute Table Base */ { reg[5] = d; satb = (d << 9) & sat_base_mask; break; } case 7: /* Backdrop color */ { reg[7] = d; /* Check if backdrop color changed */ d &= 0x3F; if (d != border) { /* Update backdrop color */ border = d; /* Reset palette entry */ if (reg[1] & 4) { /* Mode 5 */ color_update_m5(0x00, *(uint16 *)&cram[d << 1]); } else { /* Mode 4 */ color_update_m4(0x40, *(uint16 *)&cram[(0x10 | (d & 0x0F)) << 1]); } /* Backdrop color modified during HBLANK (Road Rash 1,2,3)*/ if ((v_counter < bitmap.viewport.h) && (cycles <= (mcycles_vdp + 860))) { /* remap entire line */ remap_line(v_counter); } } break; } case 8: /* Horizontal Scroll (Mode 4 only) */ { int line; /* Hscroll is latched at HCount 0xF3, HCount 0xF6 on MD */ /* Line starts at HCount 0xF4, HCount 0xF6 on MD */ if (system_hw < SYSTEM_MD) { cycles = cycles + 15; } /* Make sure Hscroll has not already been latched */ line = (lines_per_frame + (cycles / MCYCLES_PER_LINE) - 1) % lines_per_frame; if ((line > v_counter) && (line < bitmap.viewport.h) && !(work_ram[0x1ffb] & cart.special)) { v_counter = line; render_line(line); } reg[8] = d; break; } case 11: /* CTRL #3 */ { reg[11] = d; /* Horizontal scrolling mode */ hscroll_mask = hscroll_mask_table[d & 0x03]; /* Vertical Scrolling mode */ if (d & 0x04) { render_bg = im2_flag ? render_bg_m5_im2_vs : render_bg_m5_vs; } else { render_bg = im2_flag ? render_bg_m5_im2 : render_bg_m5; } break; } case 12: /* CTRL #4 */ { /* Look for changed bits */ r = d ^ reg[12]; reg[12] = d; /* Shadow & Highlight mode */ if (r & 0x08) { /* Reset color palette */ int i; color_update_m5(0x00, *(uint16 *)&cram[border << 1]); for (i = 1; i < 0x40; i++) { color_update_m5(i, *(uint16 *)&cram[i << 1]); } /* Update sprite rendering function */ if (d & 0x08) { render_obj = im2_flag ? render_obj_m5_im2_ste : render_obj_m5_ste; } else { render_obj = im2_flag ? render_obj_m5_im2 : render_obj_m5; } } /* Interlaced modes */ if (r & 0x06) { /* changes should be applied on next frame */ bitmap.viewport.changed |= 2; } /* Active display width */ if (r & 0x01) { if (d & 0x01) { /* Update display-dependant registers */ ntwb = (reg[3] << 10) & 0xF000; satb = (reg[5] << 9) & 0xFC00; sat_base_mask = 0xFC00; sat_addr_mask = 0x03FF; /* Update HC table */ hctab = cycle2hc40; /* Update clipping */ window_clip(reg[17], 1); /* Max. sprite pixels per line */ max_sprite_pixels = 320; } else { /* Update display-dependant registers */ ntwb = (reg[3] << 10) & 0xF800; satb = (reg[5] << 9) & 0xFE00; sat_base_mask = 0xFE00; sat_addr_mask = 0x01FF; /* Update HC table */ hctab = cycle2hc32; /* Update clipping */ window_clip(reg[17], 0); /* Max. sprite pixels per line */ max_sprite_pixels = 256; } /* Active display width modified during HBLANK (Bugs Bunny Double Trouble) */ if ((v_counter < bitmap.viewport.h) && (cycles <= (mcycles_vdp + 860))) { /* Update active display width */ bitmap.viewport.w = 256 + ((d & 1) << 6); /* Redraw entire line */ render_line(v_counter); } else if (v_counter == (lines_per_frame - 1)) { /* Update starting frame active display width */ bitmap.viewport.w = 256 + ((d & 1) << 6); } else { /* Changes should be applied on next frame (Golden Axe III intro) */ /* NB: not 100% accurate but required since backend framebuffer width cannot be modified mid-frame. */ /* This would require a fixed framebuffer width (based on TV screen aspect ratio) and pixel scaling */ /* to be done during rendering (depending on active display pixel aspect ratio in H32 or H40 mode). */ /* Display is generally disabled when this is modified so it shouldn't be really noticeable anyway. */ bitmap.viewport.changed |= 2; } } break; } case 13: /* HScroll Base Address */ { reg[13] = d; hscb = (d << 10) & 0xFC00; break; } case 16: /* Playfield size */ { reg[16] = d; playfield_shift = shift_table[(d & 3)]; playfield_col_mask = col_mask_table[(d & 3)]; playfield_row_mask = row_mask_table[(d >> 4) & 3]; break; } case 17: /* Window/Plane A vertical clipping */ { reg[17] = d; window_clip(d, reg[12] & 1); break; } default: { reg[r] = d; break; } } } /*--------------------------------------------------------------------------*/ /* FIFO emulation (Mega Drive VDP specific) */ /* ---------------------------------------- */ /* */ /* CPU access to VRAM, CRAM & VSRAM is limited during active display: */ /* H32 mode -> 16 access per line */ /* H40 mode -> 18 access per line */ /* */ /* with fixed access slots timings detailled below. */ /* */ /* Each VRAM access is byte wide, so one VRAM write (word) need two slots. */ /* */ /*--------------------------------------------------------------------------*/ static void vdp_fifo_update(unsigned int cycles) { int slots, count = 0; const int *fifo_timing; const int fifo_cycles_h32[16+2] = { 230, 510, 810, 970, 1130, 1450, 1610, 1770, 2090, 2250, 2410, 2730, 2890, 3050, 3350, 3370, MCYCLES_PER_LINE + 230, MCYCLES_PER_LINE + 510 }; const int fifo_cycles_h40[18+2] = { 352, 820, 948, 1076, 1332, 1460, 1588, 1844, 1972, 2100, 2356, 2484, 2612, 2868, 2996, 3124, 3364, 3380, MCYCLES_PER_LINE + 352, MCYCLES_PER_LINE + 820 }; /* number of access slots up to current line */ if (reg[12] & 0x01) { fifo_timing = fifo_cycles_h40; slots = 18 * (cycles / MCYCLES_PER_LINE); } else { fifo_timing = fifo_cycles_h32; slots = 16 * (cycles / MCYCLES_PER_LINE); } /* number of access slots within current line */ cycles = cycles % MCYCLES_PER_LINE; while (fifo_timing[count] <= cycles) { count++; } /* number of processed FIFO entries since last access */ slots = (slots + count - fifo_slots) >> fifo_byte_access; if (slots > 0) { /* process FIFO entries */ fifo_write_cnt -= slots; /* Clear FIFO full flag */ status &= 0xFEFF; if (fifo_write_cnt <= 0) { /* No more FIFO entries */ fifo_write_cnt = 0; /* Set FIFO empty flag */ status |= 0x200; } /* Update FIFO access slot counter */ fifo_slots += (slots << fifo_byte_access); } /* next FIFO update cycle */ fifo_cycles = mcycles_vdp + fifo_timing[count | fifo_byte_access]; } /*--------------------------------------------------------------------------*/ /* Internal 16-bit data bus access function (Mode 5 only) */ /*--------------------------------------------------------------------------*/ static void vdp_bus_w(unsigned int data) { /* write data to next FIFO entry */ fifo[fifo_idx] = data; /* increment FIFO write pointer */ fifo_idx = (fifo_idx + 1) & 3; /* Check destination code (CD0-CD3) */ switch (code & 0x0F) { case 0x01: /* VRAM */ { /* VRAM address */ int index = addr & 0xFFFE; /* Pointer to VRAM */ uint16 *p = (uint16 *)&vram[index]; /* Byte-swap data if A0 is set */ if (addr & 1) { data = ((data >> 8) | (data << 8)) & 0xFFFF; } /* Intercept writes to Sprite Attribute Table */ if ((index & sat_base_mask) == satb) { /* Update internal SAT */ *(uint16 *) &sat[index & sat_addr_mask] = data; } /* Only write unique data to VRAM */ if (data != *p) { int name; /* Write data to VRAM */ *p = data; /* Update pattern cache */ MARK_BG_DIRTY (index); } #ifdef LOGVDP error("[%d(%d)][%d(%d)] VRAM 0x%x write -> 0x%x (%x)\n", v_counter, m68k.cycles/MCYCLES_PER_LINE-1, m68k.cycles, m68k.cycles%MCYCLES_PER_LINE, addr, data, m68k_get_reg(M68K_REG_PC)); #endif break; } case 0x03: /* CRAM */ { /* Pointer to CRAM 9-bit word */ uint16 *p = (uint16 *)&cram[addr & 0x7E]; /* Pack 16-bit bus data (BBB0GGG0RRR0) to 9-bit CRAM data (BBBGGGRRR) */ data = ((data & 0xE00) >> 3) | ((data & 0x0E0) >> 2) | ((data & 0x00E) >> 1); /* Check if CRAM data is being modified */ if (data != *p) { /* CRAM index (64 words) */ int index = (addr >> 1) & 0x3F; /* Write CRAM data */ *p = data; /* Color entry 0 of each palette is never displayed (transparent pixel) */ if (index & 0x0F) { /* Update color palette */ color_update_m5(index, data); } /* Update backdrop color */ if (index == border) { color_update_m5(0x00, data); } /* CRAM modified during HBLANK (Striker, Zero the Kamikaze, etc) */ if ((v_counter < bitmap.viewport.h) && (reg[1]& 0x40) && (m68k.cycles <= (mcycles_vdp + 860))) { /* Remap current line */ remap_line(v_counter); } } #ifdef LOGVDP error("[%d(%d)][%d(%d)] CRAM 0x%x write -> 0x%x (%x)\n", v_counter, m68k.cycles/MCYCLES_PER_LINE-1, m68k.cycles, m68k.cycles%MCYCLES_PER_LINE, addr, data, m68k_get_reg(M68K_REG_PC)); #endif break; } case 0x05: /* VSRAM */ { *(uint16 *)&vsram[addr & 0x7E] = data; /* 2-cell Vscroll mode */ if (reg[11] & 0x04) { /* VSRAM writes during HBLANK (Adventures of Batman & Robin) */ if ((v_counter < bitmap.viewport.h) && (reg[1]& 0x40) && (m68k.cycles <= (mcycles_vdp + 860))) { /* Remap current line */ render_line(v_counter); } } #ifdef LOGVDP error("[%d(%d)][%d(%d)] VSRAM 0x%x write -> 0x%x (%x)\n", v_counter, m68k.cycles/MCYCLES_PER_LINE-1, m68k.cycles, m68k.cycles%MCYCLES_PER_LINE, addr, data, m68k_get_reg(M68K_REG_PC)); #endif break; } default: { #ifdef LOGERROR error("[%d(%d)][%d(%d)] Invalid (%d) 0x%x write -> 0x%x (%x)\n", v_counter, m68k.cycles/MCYCLES_PER_LINE-1, m68k.cycles, m68k.cycles%MCYCLES_PER_LINE, code, addr, data, m68k_get_reg(M68K_REG_PC)); #endif break; } } /* Increment address register */ addr += reg[15]; } /*--------------------------------------------------------------------------*/ /* 68k bus interface (Mega Drive VDP only) */ /*--------------------------------------------------------------------------*/ static void vdp_68k_data_w_m4(unsigned int data) { /* Clear pending flag */ pending = 0; /* Restricted VDP writes during active display */ if (!(status & 8) && (reg[1] & 0x40)) { /* Update VDP FIFO */ vdp_fifo_update(m68k.cycles); /* Clear FIFO empty flag */ status &= 0xFDFF; /* up to 4 words can be stored */ if (fifo_write_cnt < 4) { /* Increment FIFO counter */ fifo_write_cnt++; /* Set FIFO full flag if 4 words are stored */ status |= ((fifo_write_cnt & 4) << 6); } else { /* CPU is halted until next FIFO entry processing */ m68k.cycles = fifo_cycles; /* Update FIFO access slot counter */ fifo_slots = fifo_slots + 1 + fifo_byte_access; } } /* Check destination code */ if (code & 0x02) { /* CRAM index (32 words) */ int index = addr & 0x1F; /* Pointer to CRAM 9-bit word */ uint16 *p = (uint16 *)&cram[index << 1]; /* Pack 16-bit data (xxx000BBGGRR) to 9-bit CRAM data (xxxBBGGRR) */ data = ((data & 0xE00) >> 3) | (data & 0x3F); /* Check if CRAM data is being modified */ if (data != *p) { /* Write CRAM data */ *p = data; /* Update color palette */ color_update_m4(index, data); /* Update backdrop color */ if (index == (0x10 | (border & 0x0F))) { color_update_m4(0x40, data); } } } else { /* VRAM address (interleaved format) */ int index = ((addr << 1) & 0x3FC) | ((addr & 0x200) >> 8) | (addr & 0x3C00); /* Pointer to VRAM */ uint16 *p = (uint16 *)&vram[index]; /* Byte-swap data if A0 is set */ if (addr & 1) { data = ((data >> 8) | (data << 8)) & 0xFFFF; } /* Only write unique data to VRAM */ if (data != *p) { int name; /* Write data to VRAM */ *p = data; /* Update the pattern cache */ MARK_BG_DIRTY (index); } } /* Increment address register (TODO: check how address is incremented in Mode 4) */ addr += (reg[15] + 1); } static void vdp_68k_data_w_m5(unsigned int data) { /* Clear pending flag */ pending = 0; /* Restricted VDP writes during active display */ if (!(status & 8) && (reg[1] & 0x40)) { /* Update VDP FIFO */ vdp_fifo_update(m68k.cycles); /* Clear FIFO empty flag */ status &= 0xFDFF; /* up to 4 words can be stored */ if (fifo_write_cnt < 4) { /* Increment FIFO counter */ fifo_write_cnt++; /* Set FIFO full flag if 4 words are stored */ status |= ((fifo_write_cnt & 4) << 6); } else { /* CPU is halted until next FIFO entry processing (Chaos Engine / Soldiers of Fortune, Double Clutch, Titan Overdrive Demo) */ m68k.cycles = fifo_cycles; /* Update FIFO access slot counter */ fifo_slots += (1 + fifo_byte_access); } } /* Write data */ vdp_bus_w(data); /* Check if DMA Fill is pending */ if (dmafill) { /* Clear DMA Fill pending flag */ dmafill = 0; /* DMA length */ dma_length = (reg[20] << 8) | reg[19]; /* Zero DMA length (pre-decrementing counter) */ if (!dma_length) { dma_length = 0x10000; } /* Trigger DMA */ vdp_dma_update(m68k.cycles); } } static unsigned int vdp_68k_data_r_m4(void) { /* VRAM address (interleaved format) */ int index = ((addr << 1) & 0x3FC) | ((addr & 0x200) >> 8) | (addr & 0x3C00); /* Clear pending flag */ pending = 0; /* Increment address register (TODO: check how address is incremented in Mode 4) */ addr += (reg[15] + 1); /* Read VRAM data */ return *(uint16 *) &vram[index]; } static unsigned int vdp_68k_data_r_m5(void) { uint16 data = 0; /* Clear pending flag */ pending = 0; /* Check destination code (CD0-CD3) & CD4 */ switch (code & 0x1F) { case 0x00: { /* read two bytes from VRAM */ data = *(uint16 *)&vram[addr & 0xFFFE]; #ifdef LOGVDP error("[%d(%d)][%d(%d)] VRAM 0x%x read -> 0x%x (%x)\n", v_counter, m68k.cycles/MCYCLES_PER_LINE-1, m68k.cycles, m68k.cycles%MCYCLES_PER_LINE, addr, data, m68k_get_reg(M68K_REG_PC)); #endif break; } case 0x04: { /* VSRAM index */ int index = addr & 0x7E; /* Check against VSRAM max size (80 x 11-bits) */ if (index >= 0x50) { /* Wrap to address 0 (TODO: check if still true with Genesis 3 model) */ index = 0; } /* Read 11-bit word from VSRAM */ data = *(uint16 *)&vsram[index] & 0x7FF; /* Unused bits are set using data from next available FIFO entry */ data |= (fifo[fifo_idx] & ~0x7FF); #ifdef LOGVDP error("[%d(%d)][%d(%d)] VSRAM 0x%x read -> 0x%x (%x)\n", v_counter, m68k.cycles/MCYCLES_PER_LINE-1, m68k.cycles, m68k.cycles%MCYCLES_PER_LINE, addr, data, m68k_get_reg(M68K_REG_PC)); #endif break; } case 0x08: { /* Read 9-bit word from CRAM */ data = *(uint16 *)&cram[addr & 0x7E]; /* Unpack 9-bit CRAM data (BBBGGGRRR) to 16-bit bus data (BBB0GGG0RRR0) */ data = ((data & 0x1C0) << 3) | ((data & 0x038) << 2) | ((data & 0x007) << 1); /* Unused bits are set using data from next available FIFO entry */ data |= (fifo[fifo_idx] & ~0xEEE); #ifdef LOGVDP error("[%d(%d)][%d(%d)] CRAM 0x%x read -> 0x%x (%x)\n", v_counter, m68k.cycles/MCYCLES_PER_LINE-1, m68k.cycles, m68k.cycles%MCYCLES_PER_LINE, addr, data, m68k_get_reg(M68K_REG_PC)); #endif break; } case 0x0c: /* undocumented 8-bit VRAM read */ { /* Read one byte from VRAM adjacent address */ data = READ_BYTE(vram, addr ^ 1); /* Unused bits are set using data from next available FIFO entry */ data |= (fifo[fifo_idx] & ~0xFF); #ifdef LOGVDP error("[%d(%d)][%d(%d)] 8-bit VRAM 0x%x read -> 0x%x (%x)\n", v_counter, m68k.cycles/MCYCLES_PER_LINE-1, m68k.cycles, m68k.cycles%MCYCLES_PER_LINE, addr, data, m68k_get_reg(M68K_REG_PC)); #endif break; } default: { /* Invalid code value (normally locks VDP, hard reset required) */ #ifdef LOGERROR error("[%d(%d)][%d(%d)] Invalid (%d) 0x%x read (%x)\n", v_counter, m68k.cycles/MCYCLES_PER_LINE-1, m68k.cycles, m68k.cycles%MCYCLES_PER_LINE, code, addr, m68k_get_reg(M68K_REG_PC)); #endif break; } } /* Increment address register */ addr += reg[15]; /* Return data */ return data; } /*--------------------------------------------------------------------------*/ /* Z80 bus interface (Mega Drive VDP in Master System compatibility mode) */ /*--------------------------------------------------------------------------*/ static void vdp_z80_data_w_m4(unsigned int data) { /* Clear pending flag */ pending = 0; /* Check destination code */ if (code & 0x02) { /* CRAM index (32 words) */ int index = addr & 0x1F; /* Pointer to CRAM word */ uint16 *p = (uint16 *)&cram[index << 1]; /* Check if CRAM data is being modified */ if (data != *p) { /* Write CRAM data */ *p = data; /* Update color palette */ color_update_m4(index, data); /* Update backdrop color */ if (index == (0x10 | (border & 0x0F))) { color_update_m4(0x40, data); } } } else { /* VRAM address */ int index = addr & 0x3FFF; /* Only write unique data to VRAM */ if (data != vram[index]) { int name; /* Write data */ vram[index] = data; /* Update pattern cache */ MARK_BG_DIRTY(index); } } /* Increment address register (TODO: check how address is incremented in Mode 4) */ addr += (reg[15] + 1); } static void vdp_z80_data_w_m5(unsigned int data) { /* Clear pending flag */ pending = 0; /* Push byte into FIFO */ fifo[fifo_idx] = data << 8; fifo_idx = (fifo_idx + 1) & 3; /* Check destination code (CD0-CD3) */ switch (code & 0x0F) { case 0x01: /* VRAM */ { /* VRAM address (write low byte to even address & high byte to odd address) */ int index = addr ^ 1; /* Intercept writes to Sprite Attribute Table */ if ((index & sat_base_mask) == satb) { /* Update internal SAT */ WRITE_BYTE(sat, index & sat_addr_mask, data); } /* Only write unique data to VRAM */ if (data != READ_BYTE(vram, index)) { int name; /* Write data */ WRITE_BYTE(vram, index, data); /* Update pattern cache */ MARK_BG_DIRTY (index); } break; } case 0x03: /* CRAM */ { /* Pointer to CRAM word */ uint16 *p = (uint16 *)&cram[addr & 0x7E]; /* Pack 8-bit value into 9-bit CRAM data */ if (addr & 1) { /* Write high byte (0000BBB0 -> BBBxxxxxx) */ data = (*p & 0x3F) | ((data & 0x0E) << 5); } else { /* Write low byte (GGG0RRR0 -> xxxGGGRRR) */ data = (*p & 0x1C0) | ((data & 0x0E) >> 1)| ((data & 0xE0) >> 2); } /* Check if CRAM data is being modified */ if (data != *p) { /* CRAM index (64 words) */ int index = (addr >> 1) & 0x3F; /* Write CRAM data */ *p = data; /* Color entry 0 of each palette is never displayed (transparent pixel) */ if (index & 0x0F) { /* Update color palette */ color_update_m5(index, data); } /* Update backdrop color */ if (index == border) { color_update_m5(0x00, data); } } break; } case 0x05: /* VSRAM */ { /* Write low byte to even address & high byte to odd address */ WRITE_BYTE(vsram, (addr & 0x7F) ^ 1, data); break; } } /* Increment address register */ addr += reg[15]; /* Check if DMA Fill is pending */ if (dmafill) { /* Clear DMA Fill pending flag */ dmafill = 0; /* DMA length */ dma_length = (reg[20] << 8) | reg[19]; /* Zero DMA length (pre-decrementing counter) */ if (!dma_length) { dma_length = 0x10000; } /* Trigger DMA */ vdp_dma_update(Z80.cycles); } } static unsigned int vdp_z80_data_r_m4(void) { /* Read buffer */ unsigned int data = fifo[0]; /* Clear pending flag */ pending = 0; /* Process next read */ fifo[0] = vram[addr & 0x3FFF]; /* Increment address register (TODO: check how address is incremented in Mode 4) */ addr += (reg[15] + 1); /* Return data */ return data; } static unsigned int vdp_z80_data_r_m5(void) { unsigned int data = 0; /* Clear pending flag */ pending = 0; /* Check destination code (CD0-CD3) & CD4 */ switch (code & 0x1F) { case 0x00: /* VRAM */ { /* Return low byte from even address & high byte from odd address */ data = READ_BYTE(vram, addr ^ 1); break; } case 0x04: /* VSRAM */ { /* Return low byte from even address & high byte from odd address */ data = READ_BYTE(vsram, (addr & 0x7F) ^ 1); break; } case 0x08: /* CRAM */ { /* Read CRAM data */ data = *(uint16 *)&cram[addr & 0x7E]; /* Unpack 9-bit CRAM data (BBBGGGRRR) to 16-bit data (BBB0GGG0RRR0) */ data = ((data & 0x1C0) << 3) | ((data & 0x038) << 2) | ((data & 0x007) << 1); /* Return low byte from even address & high byte from odd address */ if (addr & 1) { data = data >> 8; } data &= 0xFF; break; } } /* Increment address register */ addr += reg[15]; /* Return data */ return data; } /*-----------------------------------------------------------------------------*/ /* Z80 bus interface (Master System, Game Gear & SG-1000 VDP) */ /*-----------------------------------------------------------------------------*/ static void vdp_z80_data_w_ms(unsigned int data) { /* Clear pending flag */ pending = 0; if (code < 3) { int index; /* Check if we are already on next line */ int line = (lines_per_frame + (Z80.cycles / MCYCLES_PER_LINE) - 1) % lines_per_frame; if ((line > v_counter) && (line < bitmap.viewport.h) && !(work_ram[0x1ffb] & cart.special)) { /* Render next line */ v_counter = line; render_line(line); } /* VRAM address */ index = addr & 0x3FFF; /* VRAM write */ if (data != vram[index]) { int name; vram[index] = data; MARK_BG_DIRTY(index); } #ifdef LOGVDP error("[%d(%d)][%d(%d)] VRAM 0x%x write -> 0x%x (%x)\n", v_counter, Z80.cycles/MCYCLES_PER_LINE-1, Z80.cycles, Z80.cycles%MCYCLES_PER_LINE, index, data, Z80.pc.w.l); #endif } else { /* CRAM address */ int index = addr & 0x1F; /* Pointer to CRAM word */ uint16 *p = (uint16 *)&cram[index << 1]; /* Check if CRAM data is being modified */ if (data != *p) { /* Write CRAM data */ *p = data; /* Update color palette */ color_update_m4(index, data); /* Update backdrop color */ if (index == (0x10 | (border & 0x0F))) { color_update_m4(0x40, data); } } #ifdef LOGVDP error("[%d(%d)][%d(%d)] CRAM 0x%x write -> 0x%x (%x)\n", v_counter, Z80.cycles/MCYCLES_PER_LINE-1, Z80.cycles, Z80.cycles%MCYCLES_PER_LINE, addr, data, Z80.pc.w.l); #endif } /* Update read buffer */ fifo[0] = data; /* Update address register */ addr++; } static void vdp_z80_data_w_gg(unsigned int data) { /* Clear pending flag */ pending = 0; if (code < 3) { int index; /* Check if we are already on next line*/ int line = (lines_per_frame + (Z80.cycles / MCYCLES_PER_LINE) - 1) % lines_per_frame; if ((line > v_counter) && (line < bitmap.viewport.h) && !(work_ram[0x1ffb] & cart.special)) { /* Render next line */ v_counter = line; render_line(line); } /* VRAM address */ index = addr & 0x3FFF; /* VRAM write */ if (data != vram[index]) { int name; vram[index] = data; MARK_BG_DIRTY(index); } #ifdef LOGVDP error("[%d(%d)][%d(%d)] VRAM 0x%x write -> 0x%x (%x)\n", v_counter, Z80.cycles/MCYCLES_PER_LINE-1, Z80.cycles, Z80.cycles%MCYCLES_PER_LINE, index, data, Z80.pc.w.l); #endif } else { if (addr & 1) { /* Pointer to CRAM word */ uint16 *p = (uint16 *)&cram[addr & 0x3E]; /* 12-bit data word */ data = (data << 8) | cached_write; /* Check if CRAM data is being modified */ if (data != *p) { /* Color index (0-31) */ int index = (addr >> 1) & 0x1F; /* Write CRAM data */ *p = data; /* Update color palette */ color_update_m4(index, data); /* Update backdrop color */ if (index == (0x10 | (border & 0x0F))) { color_update_m4(0x40, data); } } } else { /* Latch LSB */ cached_write = data; } #ifdef LOGVDP error("[%d(%d)][%d(%d)] CRAM 0x%x write -> 0x%x (%x)\n", v_counter, Z80.cycles/MCYCLES_PER_LINE-1, Z80.cycles, Z80.cycles%MCYCLES_PER_LINE, addr, data, Z80.pc.w.l); #endif } /* Update read buffer */ fifo[0] = data; /* Update address register */ addr++; } static void vdp_z80_data_w_sg(unsigned int data) { /* VRAM address */ int index = addr & 0x3FFF; /* Clear pending flag */ pending = 0; /* 4K address decoding (cf. tms9918a.txt) */ if (!(reg[1] & 0x80)) { index = (index & 0x203F) | ((index >> 6) & 0x40) | ((index << 1) & 0x1F80); } /* VRAM write */ vram[index] = data; /* Update address register */ addr++; #ifdef LOGVDP error("[%d(%d)][%d(%d)] VRAM 0x%x write -> 0x%x (%x)\n", v_counter, Z80.cycles/MCYCLES_PER_LINE-1, Z80.cycles, Z80.cycles%MCYCLES_PER_LINE, index, data, Z80.pc.w.l); #endif } /*--------------------------------------------------------------------------*/ /* DMA operations (Mega Drive VDP only) */ /*--------------------------------------------------------------------------*/ /* DMA from 68K bus: $000000-$7FFFFF (external area) */ static void vdp_dma_68k_ext(unsigned int length) { uint16 data; /* 68k bus source address */ uint32 source = (reg[23] << 17) | (dma_src << 1); do { /* Read data word from 68k bus */ if (m68k.memory_map[source>>16].read16) { data = m68k.memory_map[source>>16].read16(source); } else { data = *(uint16 *)(m68k.memory_map[source>>16].base + (source & 0xFFFF)); } /* Increment source address */ source += 2; /* 128k DMA window */ source = (reg[23] << 17) | (source & 0x1FFFF); /* Write data word to VRAM, CRAM or VSRAM */ vdp_bus_w(data); } while (--length); /* Update DMA source address */ dma_src = (source >> 1) & 0xffff; } /* DMA from 68K bus: $800000-$FFFFFF (internal area) except I/O area */ static void vdp_dma_68k_ram(unsigned int length) { uint16 data; /* 68k bus source address */ uint32 source = (reg[23] << 17) | (dma_src << 1); do { /* access Work-RAM by default */ data = *(uint16 *)(work_ram + (source & 0xFFFF)); /* Increment source address */ source += 2; /* 128k DMA window */ source = (reg[23] << 17) | (source & 0x1FFFF); /* Write data word to VRAM, CRAM or VSRAM */ vdp_bus_w(data); } while (--length); /* Update DMA source address */ dma_src = (source >> 1) & 0xffff; } /* DMA from 68K bus: $A00000-$A1FFFF (I/O area) specific */ static void vdp_dma_68k_io(unsigned int length) { uint16 data; /* 68k bus source address */ uint32 source = (reg[23] << 17) | (dma_src << 1); do { /* Z80 area */ if (source <= 0xA0FFFF) { /* Return $FFFF only when the Z80 isn't hogging the Z-bus. (e.g. Z80 isn't reset and 68000 has the bus) */ data = ((zstate ^ 3) ? *(uint16 *)(work_ram + (source & 0xFFFF)) : 0xFFFF); } /* The I/O chip and work RAM try to drive the data bus which results in both values being combined in random ways when read. We return the I/O chip values which seem to have precedence, */ else if (source <= 0xA1001F) { data = io_68k_read((source >> 1) & 0x0F); data = (data << 8 | data); } /* All remaining locations access work RAM */ else { data = *(uint16 *)(work_ram + (source & 0xFFFF)); } /* Increment source address */ source += 2; /* 128k DMA window */ source = (reg[23] << 17) | (source & 0x1FFFF); /* Write data to VRAM, CRAM or VSRAM */ vdp_bus_w(data); } while (--length); /* Update DMA source address */ dma_src = (source >> 1) & 0xffff; } /* VRAM Copy */ static void vdp_dma_copy(unsigned int length) { /* CD4 should be set (CD0-CD3 ignored) otherwise VDP locks (hard reset needed) */ if (code & 0x10) { int name; uint8 data; /* VRAM source address */ uint16 source = dma_src; do { /* Read byte from adjacent VRAM source address */ data = READ_BYTE(vram, source ^ 1); /* Intercept writes to Sprite Attribute Table */ if ((addr & sat_base_mask) == satb) { /* Update internal SAT */ WRITE_BYTE(sat, (addr & sat_addr_mask) ^ 1, data); } /* Write byte to adjacent VRAM destination address */ WRITE_BYTE(vram, addr ^ 1, data); /* Update pattern cache */ MARK_BG_DIRTY(addr); /* Increment VRAM source address */ source++; /* Increment VRAM destination address */ addr += reg[15]; } while (--length); /* Update DMA source address */ dma_src = source; } } /* DMA Fill */ static void vdp_dma_fill(unsigned int length) { /* Check destination code (CD0-CD3) */ switch (code & 0x0F) { case 0x01: /* VRAM */ { int name; /* Get source data from last written FIFO entry */ uint8 data = fifo[(fifo_idx+3)&3] >> 8; do { /* Intercept writes to Sprite Attribute Table */ if ((addr & sat_base_mask) == satb) { /* Update internal SAT */ WRITE_BYTE(sat, (addr & sat_addr_mask) ^ 1, data); } /* Write byte to adjacent VRAM address */ WRITE_BYTE(vram, addr ^ 1, data); /* Update pattern cache */ MARK_BG_DIRTY (addr); /* Increment VRAM address */ addr += reg[15]; } while (--length); break; } case 0x03: /* CRAM */ { /* Get source data from next available FIFO entry */ uint16 data = fifo[fifo_idx]; /* Pack 16-bit bus data (BBB0GGG0RRR0) to 9-bit CRAM data (BBBGGGRRR) */ data = ((data & 0xE00) >> 3) | ((data & 0x0E0) >> 2) | ((data & 0x00E) >> 1); do { /* Pointer to CRAM 9-bit word */ uint16 *p = (uint16 *)&cram[addr & 0x7E]; /* Check if CRAM data is being modified */ if (data != *p) { /* CRAM index (64 words) */ int index = (addr >> 1) & 0x3F; /* Write CRAM data */ *p = data; /* Color entry 0 of each palette is never displayed (transparent pixel) */ if (index & 0x0F) { /* Update color palette */ color_update_m5(index, data); } /* Update backdrop color */ if (index == border) { color_update_m5(0x00, data); } } /* Increment CRAM address */ addr += reg[15]; } while (--length); break; } case 0x05: /* VSRAM */ { /* Get source data from next available FIFO entry */ uint16 data = fifo[fifo_idx]; do { /* Write VSRAM data */ *(uint16 *)&vsram[addr & 0x7E] = data; /* Increment VSRAM address */ addr += reg[15]; } while (--length); break; } default: { /* invalid destination does nothing (Williams Greatest Hits after soft reset) */ /* address is still incremented */ addr += reg[15] * length; } } }