/* * video.cpp - Video/graphics emulation * * Basilisk II (C) 1997-2008 Christian Bauer * Portions written by Marc Hellwig * * 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 */ /* * SEE ALSO * Inside Macintosh: Devices, chapter 1 "Device Manager" * Designing Cards and Drivers for the Macintosh Family, Second Edition * Designing PCI Cards and Drivers for Power Macintosh Computers * Display Device Driver Guide */ #include #include "sysdeps.h" #include "cpu_emulation.h" #include "main.h" #include "macos_util.h" #include "slot_rom.h" #include "video.h" #include "video_defs.h" #define DEBUG 0 #include "debug.h" // Next available NuBus slot ID uint8 monitor_desc::next_slot_id = 0x80; // Vector of pointers to available monitor descriptions, filled by VideoInit() vector VideoMonitors; /* * Converts a video_depth to a C-String name ("VDEPTH_1BIT", "VDEPTH_2BIT", etc.) */ const char * NameOfDepth(video_depth depth) { switch (depth) { case VDEPTH_1BIT: return "VDEPTH_1BIT"; case VDEPTH_2BIT: return "VDEPTH_2BIT"; case VDEPTH_4BIT: return "VDEPTH_4BIT"; case VDEPTH_8BIT: return "VDEPTH_8BIT"; case VDEPTH_16BIT: return "VDEPTH_16BIT"; case VDEPTH_32BIT: return "VDEPTH_32BIT"; } return ""; } /* * Find palette size for given color depth */ static int palette_size(video_depth depth) { switch (depth) { case VDEPTH_1BIT: return 2; case VDEPTH_2BIT: return 4; case VDEPTH_4BIT: return 16; case VDEPTH_8BIT: return 256; case VDEPTH_16BIT: return 32; case VDEPTH_32BIT: return 256; default: return 0; } } /* * Find pointer to monitor_desc for given slot ID (or NULL if not found) */ static monitor_desc *find_monitor(uint8 id) { vector::const_iterator i, end = VideoMonitors.end(); for (i = VideoMonitors.begin(); i != end; ++i) { if ((*i)->get_slot_id() == id) return *i; } return NULL; } /* * monitor_desc constructor */ monitor_desc::monitor_desc(const vector &available_modes, video_depth default_depth, uint32 default_id) : modes(available_modes) { // Assign the next slot ID on construction slot_id = next_slot_id++; // Initialize Apple mode list uint16 mode = 0x80; for (int depth = VDEPTH_1BIT; depth <= VDEPTH_32BIT; depth++) { if (has_depth(video_depth(depth))) apple_mode_for_depth[depth] = mode++; else apple_mode_for_depth[depth] = 0; } // Set default mode current_mode = find_mode(depth_to_apple_mode(default_depth), default_id); } /* * Get bytes-per-row value for specified resolution/depth * (if the mode isn't supported, make a good guess) */ uint32 monitor_desc::get_bytes_per_row(video_depth depth, uint32 id) const { vector::const_iterator i, end = modes.end(); for (i = modes.begin(); i != end; ++i) { if (i->depth == depth && i->resolution_id == id) return i->bytes_per_row; } uint32 x, y; get_size_of_resolution(id, x, y); return TrivialBytesPerRow(x, depth); } /* * Check whether a mode with the specified depth exists on this display */ bool monitor_desc::has_depth(video_depth depth) const { vector::const_iterator i = modes.begin(), end = modes.end(); while (i != end) { if (i->depth == depth) return true; ++i; } return false; } /* * Check whether the specified resolution ID is one of the supported resolutions */ bool monitor_desc::has_resolution(uint32 id) const { vector::const_iterator i, end = modes.end(); for (i = modes.begin(); i != end; ++i) { if (i->resolution_id == id) return true; } return false; } /* * Find specified mode (depth/resolution) (or invalid_mode() if not found) */ vector::const_iterator monitor_desc::find_mode(uint16 apple_mode, uint32 id) const { vector::const_iterator i, end = modes.end(); for (i = modes.begin(); i != end; ++i) { if (i->resolution_id == id && depth_to_apple_mode(i->depth) == apple_mode) return i; } return i; } /* * Find maximum supported depth for given resolution ID */ video_depth monitor_desc::max_depth_of_resolution(uint32 id) const { video_depth m = VDEPTH_1BIT; vector::const_iterator i, end = modes.end(); for (i = modes.begin(); i != end; ++i) { if (i->depth > m) m = i->depth; } return m; } /* * Get X/Y size of specified resolution */ void monitor_desc::get_size_of_resolution(uint32 id, uint32 &x, uint32 &y) const { vector::const_iterator i, end = modes.end(); for (i = modes.begin(); i != end; ++i) { if (i->resolution_id == id) { x = i->x; y = i->y; return; } } x = y = 0; } /* * Set palette to 50% gray */ void monitor_desc::set_gray_palette(void) { for (int i=0; i<256; i++) { palette[i * 3 + 0] = 127; palette[i * 3 + 1] = 127; palette[i * 3 + 2] = 127; } set_palette(palette, 256); } /* * Load gamma-corrected black-to-white ramp */ void monitor_desc::load_gamma_ramp(void) { // Find tables for gamma correction uint8 *red_gamma = NULL, *green_gamma = NULL, *blue_gamma = NULL; bool have_gamma = false; int data_width = 0; if (gamma_table) { uint32 table = gamma_table; red_gamma = Mac2HostAddr(table + gFormulaData + ReadMacInt16(table + gFormulaSize)); int chan_cnt = ReadMacInt16(table + gChanCnt); if (chan_cnt == 1) green_gamma = blue_gamma = red_gamma; else { int ofs = ReadMacInt16(table + gDataCnt); green_gamma = red_gamma + ofs; blue_gamma = green_gamma + ofs; } data_width = ReadMacInt16(table + gDataWidth); have_gamma = true; } int num = (current_mode->depth == VDEPTH_16BIT ? 32 : 256); uint8 *p = palette; for (int i=0; i> (8 - data_width)]; green = green_gamma[green >> (8 - data_width)]; blue = blue_gamma[blue >> (8 - data_width)]; } *p++ = red; *p++ = green; *p++ = blue; } set_gamma(palette, num); } /* * Allocate gamma table of specified size */ bool monitor_desc::allocate_gamma_table(int size) { M68kRegisters r; if (size > alloc_gamma_table_size) { if (gamma_table) { r.a[0] = gamma_table; Execute68kTrap(0xa01f, &r); // DisposePtr() gamma_table = 0; alloc_gamma_table_size = 0; } r.d[0] = size; Execute68kTrap(0xa71e, &r); // NewPtrSysClear() if (r.a[0] == 0) return false; gamma_table = r.a[0]; alloc_gamma_table_size = size; } return true; } /* * Set gamma table (0 = build linear ramp) */ int16 monitor_desc::set_gamma_table(uint32 user_table) { if (user_table == 0) { // Build linear ramp, 256 entries // Allocate new table, if necessary if (!allocate_gamma_table(SIZEOF_GammaTbl + 256)) return memFullErr; // Initialize header WriteMacInt16(gamma_table + gVersion, 0); WriteMacInt16(gamma_table + gType, 0); WriteMacInt16(gamma_table + gFormulaSize, 0); WriteMacInt16(gamma_table + gChanCnt, 1); WriteMacInt16(gamma_table + gDataCnt, 256); WriteMacInt16(gamma_table + gDataWidth, 8); // Build ramp uint32 p = gamma_table + gFormulaData; for (int i=0; i<256; i++) WriteMacInt8(p + i, i); } else { // User-supplied gamma table // Validate header if (ReadMacInt16(user_table + gVersion)) return paramErr; if (ReadMacInt16(user_table + gType)) return paramErr; int chan_cnt = ReadMacInt16(user_table + gChanCnt); if (chan_cnt != 1 && chan_cnt != 3) return paramErr; int data_width = ReadMacInt16(user_table + gDataWidth); if (data_width > 8) return paramErr; int data_cnt = ReadMacInt16(user_table + gDataCnt); if (data_cnt != (1 << data_width)) return paramErr; // Allocate new table, if necessary int size = SIZEOF_GammaTbl + ReadMacInt16(user_table + gFormulaSize) + chan_cnt * data_cnt; if (!allocate_gamma_table(size)) return memFullErr; // Copy table Mac2Mac_memcpy(gamma_table, user_table, size); } load_gamma_ramp(); return noErr; } /* * Switch video mode */ void monitor_desc::switch_mode(vector::const_iterator it, uint32 param, uint32 dce) { const video_mode &mode = *it; // Switch mode set_gray_palette(); current_mode = it; switch_to_current_mode(); // Update variables current_apple_mode = depth_to_apple_mode(mode.depth); current_id = mode.resolution_id; M68kRegisters r; r.a[0] = slot_param; // Find functional sResource for this display WriteMacInt8(slot_param + spSlot, ReadMacInt8(dce + dCtlSlot)); WriteMacInt8(slot_param + spID, ReadMacInt8(dce + dCtlSlotId)); WriteMacInt8(slot_param + spExtDev, 0); r.d[0] = 0x0016; Execute68kTrap(0xa06e, &r); // SRsrcInfo() uint32 rsrc = ReadMacInt32(slot_param + spPointer); // Patch minorBase (otherwise rebooting won't work) WriteMacInt8(slot_param + spID, 0x0a); // minorBase r.d[0] = 0x0006; Execute68kTrap(0xa06e, &r); // SFindStruct() uint32 minor_base = ReadMacInt32(slot_param + spPointer) - ROMBaseMac; ROMBaseHost[minor_base + 0] = mac_frame_base >> 24; ROMBaseHost[minor_base + 1] = mac_frame_base >> 16; ROMBaseHost[minor_base + 2] = mac_frame_base >> 8; ROMBaseHost[minor_base + 3] = mac_frame_base; // Patch video mode parameter table WriteMacInt32(slot_param + spPointer, rsrc); WriteMacInt8(slot_param + spID, depth_to_apple_mode(mode.depth)); r.d[0] = 0x0006; Execute68kTrap(0xa06e, &r); // SFindStruct() WriteMacInt8(slot_param + spID, 0x01); r.d[0] = 0x0006; Execute68kTrap(0xa06e, &r); // SFindStruct() uint32 p = ReadMacInt32(slot_param + spPointer) - ROMBaseMac; ROMBaseHost[p + 8] = mode.bytes_per_row >> 8; ROMBaseHost[p + 9] = mode.bytes_per_row; ROMBaseHost[p + 14] = mode.y >> 8; ROMBaseHost[p + 15] = mode.y; ROMBaseHost[p + 16] = mode.x >> 8; ROMBaseHost[p + 17] = mode.x; // Recalculate slot ROM checksum ChecksumSlotROM(); // Update sResource WriteMacInt8(slot_param + spID, ReadMacInt8(dce + dCtlSlotId)); r.d[0] = 0x002b; Execute68kTrap(0xa06e, &r); // SUpdateSRT() // Update frame buffer base in DCE and param block WriteMacInt32(dce + dCtlDevBase, mac_frame_base); WriteMacInt32(param + csBaseAddr, mac_frame_base); // Patch frame buffer base address for MacOS versions <7.6 if (!dm_present) { // Only do this when no Display Manager seems to be present; otherwise, the screen will not get redrawn D(bug("No Display Manager, patching frame buffer base\n")); WriteMacInt32(0x824, mac_frame_base); // ScrnBase WriteMacInt32(0x898, mac_frame_base); // CrsrBase uint32 gdev = ReadMacInt32(0x8a4); // MainDevice D(bug("MainDevice handle at %08lx\n", gdev)); if (gdev != 0 && gdev != 0xffffffff) { gdev = ReadMacInt32(gdev); D(bug(" pointer at %08lx\n", gdev)); uint32 pmap = ReadMacInt32(gdev + 0x16); // gdPMap D(bug(" PixMap handle at %08lx\n", pmap)); pmap = ReadMacInt32(pmap); D(bug(" pointer at %08lx\n", pmap)); WriteMacInt32(pmap, mac_frame_base); // baseAddr } gdev = ReadMacInt32(0xcc8); // TheGDevice D(bug("TheGDevice handle at %08lx\n", gdev)); } } /* * Driver Open() routine */ int16 monitor_desc::driver_open(void) { // This shouldn't happen unless the platform-specific video code is broken if (modes.empty()) fprintf(stderr, "No valid video modes found (broken video driver?)\n"); // Init local variables luminance_mapping = false; interrupts_enabled = false; current_apple_mode = preferred_apple_mode = depth_to_apple_mode(current_mode->depth); current_id = preferred_id = current_mode->resolution_id; dm_present = false; // Allocate Slot Manager parameter block in Mac RAM M68kRegisters r; r.d[0] = SIZEOF_SPBlock; Execute68kTrap(0xa71e, &r); // NewPtrSysClear() if (r.a[0] == 0) return memFullErr; slot_param = r.a[0]; D(bug("SPBlock at %08x\n", slot_param)); // Find and set default gamma table gamma_table = 0; alloc_gamma_table_size = 0; set_gamma_table(0); // Init color palette (solid gray) set_gray_palette(); return noErr; } int16 VideoDriverOpen(uint32 pb, uint32 dce) { uint8 slot_id = ReadMacInt8(dce + dCtlSlotId); D(bug("VideoDriverOpen slot %02x\n", slot_id)); monitor_desc *m = find_monitor(slot_id); if (m) return m->driver_open(); else return nsDrvErr; } /* * Driver Control() routine */ int16 monitor_desc::driver_control(uint16 code, uint32 param, uint32 dce) { switch (code) { case cscSetMode: { // Set color depth uint16 mode = ReadMacInt16(param + csMode); D(bug(" SetMode %04x\n", mode)); // Set old base address in case the switch fails WriteMacInt32(param + csBaseAddr, mac_frame_base); if (ReadMacInt16(param + csPage)) return paramErr; if (mode != current_apple_mode) { vector::const_iterator i = find_mode(mode, current_id); if (i == invalid_mode()) return paramErr; switch_mode(i, param, dce); } D(bug(" base %08x\n", mac_frame_base)); return noErr; } case cscSetEntries: // Set palette case cscDirectSetEntries: { D(bug(" (Direct)SetEntries table %08x, count %d, start %d\n", ReadMacInt32(param + csTable), ReadMacInt16(param + csCount), ReadMacInt16(param + csStart))); bool is_direct = IsDirectMode(*current_mode); if (code == cscSetEntries && is_direct) return controlErr; if (code == cscDirectSetEntries && !is_direct) return controlErr; uint32 s_pal = ReadMacInt32(param + csTable); // Source palette uint8 *d_pal; // Destination palette uint16 start = ReadMacInt16(param + csStart); uint16 count = ReadMacInt16(param + csCount); if (s_pal == 0 || count > 255) return paramErr; // Find tables for gamma correction uint8 *red_gamma = NULL, *green_gamma = NULL, *blue_gamma = NULL; bool have_gamma = false; int data_width = 0; if (gamma_table) { red_gamma = Mac2HostAddr(gamma_table + gFormulaData + ReadMacInt16(gamma_table + gFormulaSize)); int chan_cnt = ReadMacInt16(gamma_table + gChanCnt); if (chan_cnt == 1) green_gamma = blue_gamma = red_gamma; else { int ofs = ReadMacInt16(gamma_table + gDataCnt); green_gamma = red_gamma + ofs; blue_gamma = green_gamma + ofs; } data_width = ReadMacInt16(gamma_table + gDataWidth); have_gamma = true; } // Convert palette if (start == 0xffff) { // Indexed for (uint32 i=0; i<=count; i++) { d_pal = palette + (ReadMacInt16(s_pal) & 0xff) * 3; uint8 red = (uint16)ReadMacInt16(s_pal + 2) >> 8; uint8 green = (uint16)ReadMacInt16(s_pal + 4) >> 8; uint8 blue = (uint16)ReadMacInt16(s_pal + 6) >> 8; if (luminance_mapping && !is_direct) red = green = blue = (red * 0x4ccc + green * 0x970a + blue * 0x1c29) >> 16; if (have_gamma) { red = red_gamma[red >> (8 - data_width)]; green = green_gamma[green >> (8 - data_width)]; blue = blue_gamma[blue >> (8 - data_width)]; } *d_pal++ = red; *d_pal++ = green; *d_pal++ = blue; s_pal += 8; } } else { // Sequential if (start + count > 255) return paramErr; d_pal = palette + start * 3; for (uint32 i=0; i<=count; i++) { uint8 red = (uint16)ReadMacInt16(s_pal + 2) >> 8; uint8 green = (uint16)ReadMacInt16(s_pal + 4) >> 8; uint8 blue = (uint16)ReadMacInt16(s_pal + 6) >> 8; if (luminance_mapping && !is_direct) red = green = blue = (red * 0x4ccc + green * 0x970a + blue * 0x1c29) >> 16; if (have_gamma) { red = red_gamma[red >> (8 - data_width)]; green = green_gamma[green >> (8 - data_width)]; blue = blue_gamma[blue >> (8 - data_width)]; } *d_pal++ = red; *d_pal++ = green; *d_pal++ = blue; s_pal += 8; } } set_palette(palette, palette_size(current_mode->depth)); return noErr; } case cscSetGamma: { // Set gamma table uint32 user_table = ReadMacInt32(param + csGTable); D(bug(" SetGamma %08x\n", user_table)); return set_gamma_table(user_table); } case cscGrayPage: { // Fill page with dithered gray pattern D(bug(" GrayPage %d\n", ReadMacInt16(param + csPage))); if (ReadMacInt16(param + csPage)) return paramErr; uint32 pattern[6] = { 0xaaaaaaaa, // 1 bpp 0xcccccccc, // 2 bpp 0xf0f0f0f0, // 4 bpp 0xff00ff00, // 8 bpp 0xffff0000, // 16 bpp 0xffffffff // 32 bpp }; uint32 p = mac_frame_base; uint32 pat = pattern[current_mode->depth]; bool invert = (current_mode->depth == VDEPTH_32BIT); for (uint32 y=0; yy; y++) { for (uint32 x=0; xbytes_per_row; x+=4) { WriteMacInt32(p + x, pat); if (invert) pat = ~pat; } p += current_mode->bytes_per_row; pat = ~pat; } load_gamma_ramp(); return noErr; } case cscSetGray: // Enable/disable luminance mapping D(bug(" SetGray %02x\n", ReadMacInt8(param + csMode))); luminance_mapping = ReadMacInt8(param + csMode) != 0; return noErr; case cscSetInterrupt: // Enable/disable VBL D(bug(" SetInterrupt %02x\n", ReadMacInt8(param + csMode))); interrupts_enabled = (ReadMacInt8(param + csMode) == 0); return noErr; case cscSetDefaultMode: { // Set default color depth uint16 mode = ReadMacInt8(param + csMode); D(bug(" SetDefaultMode %02x\n", mode)); preferred_apple_mode = mode; return noErr; } case cscSwitchMode: { // Switch video mode (depth and resolution) uint16 mode = ReadMacInt16(param + csMode); uint32 id = ReadMacInt32(param + csData); D(bug(" SwitchMode %04x, %08x\n", mode, id)); // Set old base address in case the switch fails WriteMacInt32(param + csBaseAddr, mac_frame_base); if (ReadMacInt16(param + csPage)) return paramErr; if (mode != current_apple_mode || id != current_id) { vector::const_iterator i = find_mode(mode, id); if (i == invalid_mode()) return paramErr; switch_mode(i, param, dce); } D(bug(" base %08x\n", mac_frame_base)); return noErr; } case cscSavePreferredConfiguration: { uint16 mode = ReadMacInt16(param + csMode); uint32 id = ReadMacInt32(param + csData); D(bug(" SavePreferredConfiguration %04x, %08x\n", mode, id)); preferred_apple_mode = mode; preferred_id = id; return noErr; } default: printf("WARNING: Unknown VideoDriverControl(%d)\n", code); return controlErr; } } int16 VideoDriverControl(uint32 pb, uint32 dce) { uint8 slot_id = ReadMacInt8(dce + dCtlSlotId); uint16 code = ReadMacInt16(pb + csCode); uint32 param = ReadMacInt32(pb + csParam); D(bug("VideoDriverControl slot %02x, code %d\n", slot_id, code)); monitor_desc *m = find_monitor(slot_id); if (m) return m->driver_control(code, param, dce); else return nsDrvErr; } /* * Driver Status() routine */ int16 monitor_desc::driver_status(uint16 code, uint32 param) { switch (code) { case cscGetMode: // Get current color depth D(bug(" GetMode -> %04x, base %08x\n", current_apple_mode, mac_frame_base)); WriteMacInt16(param + csMode, current_apple_mode); WriteMacInt16(param + csPage, 0); WriteMacInt32(param + csBaseAddr, mac_frame_base); return noErr; case cscGetEntries: { // Read palette D(bug(" GetEntries table %08x, count %d, start %d\n", ReadMacInt32(param + csTable), ReadMacInt16(param + csCount), ReadMacInt16(param + csStart))); uint8 *s_pal; // Source palette uint32 d_pal = ReadMacInt32(param + csTable); // Destination palette uint16 start = ReadMacInt16(param + csStart); uint16 count = ReadMacInt16(param + csCount); if (d_pal == 0 || count > 255) return paramErr; if (start == 0xffff) { // Indexed for (uint32 i=0; i<=count; i++) { s_pal = palette + (ReadMacInt16(d_pal) & 0xff) * 3; uint8 red = *s_pal++; uint8 green = *s_pal++; uint8 blue = *s_pal++; WriteMacInt16(d_pal + 2, red * 0x0101); WriteMacInt16(d_pal + 4, green * 0x0101); WriteMacInt16(d_pal + 6, blue * 0x0101); d_pal += 8; } } else { // Sequential if (start + count > 255) return paramErr; s_pal = palette + start * 3; for (uint32 i=0; i<=count; i++) { uint8 red = *s_pal++; uint8 green = *s_pal++; uint8 blue = *s_pal++; WriteMacInt16(d_pal + 2, red * 0x0101); WriteMacInt16(d_pal + 4, green * 0x0101); WriteMacInt16(d_pal + 6, blue * 0x0101); d_pal += 8; } } return noErr; } case cscGetPages: // Get number of pages D(bug(" GetPages -> 1\n")); WriteMacInt16(param + csPage, 1); return noErr; case cscGetBaseAddress: // Get page base address D(bug(" GetBaseAddress -> %08x\n", mac_frame_base)); WriteMacInt32(param + csBaseAddr, mac_frame_base); if (ReadMacInt16(param + csPage)) return paramErr; else return noErr; case cscGetGray: // Get luminance mapping flag D(bug(" GetGray -> %d\n", luminance_mapping)); WriteMacInt8(param, luminance_mapping ? 1 : 0); return noErr; case cscGetInterrupt: // Get interrupt disable flag D(bug(" GetInterrupt -> %d\n", interrupts_enabled)); WriteMacInt8(param, interrupts_enabled ? 0 : 1); return noErr; case cscGetGamma: D(bug(" GetGamma -> %08x\n", gamma_table)); WriteMacInt32(param + csGTable, gamma_table); return noErr; case cscGetDefaultMode: // Get default color depth D(bug(" GetDefaultMode -> %02x\n", preferred_apple_mode)); WriteMacInt8(param + csMode, preferred_apple_mode); return noErr; case cscGetCurrentMode: // Get current video mode (depth and resolution) D(bug(" GetCurMode -> %04x/%08x, base %08x\n", current_apple_mode, current_id, mac_frame_base)); WriteMacInt16(param + csMode, current_apple_mode); WriteMacInt32(param + csData, current_id); WriteMacInt16(param + csPage, 0); WriteMacInt32(param + csBaseAddr, mac_frame_base); return noErr; case cscGetConnection: // Get monitor information D(bug(" GetConnection\n")); WriteMacInt16(param + csDisplayType, 8); // Modeless connection WriteMacInt8(param + csConnectTaggedType, 0); WriteMacInt8(param + csConnectTaggedData, 0); WriteMacInt32(param + csConnectFlags, 0x43); // All modes valid and safe, non-standard tagging WriteMacInt32(param + csDisplayComponent, 0); return noErr; case cscGetModeTiming: { // Get video timing for specified resolution uint32 id = ReadMacInt32(param + csTimingMode); D(bug(" GetModeTiming %08x\n", id)); if (!has_resolution(id)) return paramErr; WriteMacInt32(param + csTimingFormat, FOURCC('d', 'e', 'c', 'l')); WriteMacInt32(param + csTimingData, 0); // unknown uint32 flags = 0xb; // mode valid, safe and shown in Monitors panel if (id == preferred_id) flags |= 4; // default mode WriteMacInt32(param + csTimingFlags, flags); return noErr; } case cscGetModeBaseAddress: // Get frame buffer base address D(bug(" GetModeBaseAddress -> base %08x\n", mac_frame_base)); WriteMacInt32(param + csBaseAddr, mac_frame_base); return noErr; case cscGetPreferredConfiguration: // Get default video mode (depth and resolution) D(bug(" GetPreferredConfiguration -> %04x/%08x\n", preferred_apple_mode, preferred_id)); WriteMacInt16(param + csMode, preferred_apple_mode); WriteMacInt32(param + csData, preferred_id); return noErr; case cscGetNextResolution: { // Called iteratively to obtain a list of all supported resolutions uint32 id = ReadMacInt32(param + csPreviousDisplayModeID); D(bug(" GetNextResolution %08x\n", id)); switch (id) { case 0: // Return current resolution id = current_id; break; case 0xfffffffe: // Return first supported resolution id = 0x80; while (!has_resolution(id)) id++; break; default: // Get next resolution if (!has_resolution(id)) return paramErr; id++; while (!has_resolution(id) && id < 0x100) id++; if (id == 0x100) { // No more resolutions WriteMacInt32(param + csRIDisplayModeID, 0xfffffffd); return noErr; } break; } WriteMacInt32(param + csRIDisplayModeID, id); uint32 x, y; get_size_of_resolution(id, x, y); WriteMacInt32(param + csHorizontalPixels, x); WriteMacInt32(param + csVerticalLines, y); WriteMacInt32(param + csRefreshRate, 75 << 16); WriteMacInt16(param + csMaxDepthMode, depth_to_apple_mode(max_depth_of_resolution(id))); WriteMacInt32(param + csResolutionFlags, 0); return noErr; } case cscGetVideoParameters: { // Get information about specified resolution/depth uint32 id = ReadMacInt32(param + csDisplayModeID); uint16 mode = ReadMacInt16(param + csDepthMode); D(bug(" GetVideoParameters %04x/%08x\n", mode, id)); dm_present = true; // Display Manager seems to be present D(bug(" Display Manager detected\n")); vector::const_iterator i, end = modes.end(); for (i = modes.begin(); i != end; ++i) { if (depth_to_apple_mode(i->depth) == mode && i->resolution_id == id) { uint32 vp = ReadMacInt32(param + csVPBlockPtr); WriteMacInt32(vp + vpBaseOffset, 0); WriteMacInt16(vp + vpRowBytes, i->bytes_per_row); WriteMacInt16(vp + vpBounds, 0); WriteMacInt16(vp + vpBounds + 2, 0); WriteMacInt16(vp + vpBounds + 4, i->y); WriteMacInt16(vp + vpBounds + 6, i->x); WriteMacInt16(vp + vpVersion, 0); WriteMacInt16(vp + vpPackType, 0); WriteMacInt32(vp + vpPackSize, 0); WriteMacInt32(vp + vpHRes, 0x00480000); // 72 dpi WriteMacInt32(vp + vpVRes, 0x00480000); uint32 pix_type, pix_size, cmp_count, cmp_size, dev_type; switch (i->depth) { case VDEPTH_16BIT: pix_type = 0x10; pix_size = 16; cmp_count = 3; cmp_size = 5; dev_type = 2; // direct break; case VDEPTH_32BIT: pix_type = 0x10; pix_size = 32; cmp_count = 3; cmp_size = 8; dev_type = 2; // direct break; default: pix_type = 0; pix_size = 1 << i->depth; cmp_count = 1; cmp_size = 1 << i->depth; dev_type = 0; // CLUT break; } WriteMacInt16(vp + vpPixelType, pix_type); WriteMacInt16(vp + vpPixelSize, pix_size); WriteMacInt16(vp + vpCmpCount, cmp_count); WriteMacInt16(vp + vpCmpSize, cmp_size); WriteMacInt32(param + csPageCount, 1); WriteMacInt32(param + csDeviceType, dev_type); return noErr; } } return paramErr; // specified resolution/depth not supported } case cscGetMultiConnect: { uint32 conn = ReadMacInt32(param + csDisplayCountOrNumber); D(bug(" GetMultiConnect %08x\n", conn)); if (conn == 0xffffffff) { // Get number of connections WriteMacInt32(param + csDisplayCountOrNumber, 1); // Single-headed return noErr; } else if (conn == 1) { // Get information about first connection WriteMacInt16(param + csConnectInfo + csDisplayType, 8); // Modeless connection WriteMacInt8(param + csConnectInfo + csConnectTaggedType, 0); WriteMacInt8(param + csConnectInfo + csConnectTaggedData, 0); WriteMacInt32(param + csConnectInfo + csConnectFlags, 0x43); // All modes valid and safe, non-standard tagging WriteMacInt32(param + csConnectInfo + csDisplayComponent, 0); return noErr; } else return paramErr; } default: printf("WARNING: Unknown VideoDriverStatus(%d)\n", code); return statusErr; } } int16 VideoDriverStatus(uint32 pb, uint32 dce) { uint8 slot_id = ReadMacInt8(dce + dCtlSlotId); uint16 code = ReadMacInt16(pb + csCode); uint32 param = ReadMacInt32(pb + csParam); D(bug("VideoDriverStatus slot %02x, code %d\n", slot_id, code)); monitor_desc *m = find_monitor(slot_id); if (m) return m->driver_status(code, param); else return nsDrvErr; }