// Emacs style mode select -*- C++ -*- //----------------------------------------------------------------------------- // // $Id:$ // // Copyright (C) 1993-1996 by id Software, Inc. // // This source is available for distribution and/or modification // only under the terms of the DOOM Source Code License as // published by id Software. All rights reserved. // // The source is distributed in the hope that it will be useful, // but WITHOUT ANY WARRANTY; without even the implied warranty of // FITNESS FOR A PARTICULAR PURPOSE. See the DOOM Source Code License // for more details. // // $Log:$ // // DESCRIPTION: // Functions to draw patches (by post) directly to screen-> // Functions to blit a block to the screen-> // //----------------------------------------------------------------------------- #include #include "i_system.h" #include "x86.h" #include "i_video.h" #include "r_state.h" #include "doomdef.h" #include "doomdata.h" #include "doomstat.h" #include "c_console.h" #include "hu_stuff.h" #include "m_argv.h" #include "m_bbox.h" #include "m_swap.h" #include "i_video.h" #include "v_video.h" #include "v_text.h" #include "sc_man.h" #include "w_wad.h" #include "c_cvars.h" #include "c_dispatch.h" #include "cmdlib.h" #include "gi.h" #include "templates.h" #include "sbar.h" #include "hardware.h" #include "r_data/r_translate.h" #include "f_wipe.h" #include "m_png.h" #include "colormatcher.h" #include "v_palette.h" #include "r_sky.h" #include "r_utility.h" #include "r_renderer.h" #include "menu/menu.h" #include "r_data/voxels.h" #include "vm.h" EXTERN_CVAR(Bool, r_blendmethod) int active_con_scale(); FRenderer *Renderer; EXTERN_CVAR (Bool, swtruecolor) EXTERN_CVAR (Bool, fullscreen) #if defined(_DEBUG) && defined(_M_IX86) && !defined(__MINGW32__) #define DBGBREAK { __asm int 3 } #else #define DBGBREAK #endif class DDummyFrameBuffer : public DFrameBuffer { typedef DFrameBuffer Super; public: DDummyFrameBuffer (int width, int height) : DFrameBuffer (0, 0, false) { Width = width; Height = height; } bool Lock(bool buffered) { DBGBREAK; return false; } void Update() { DBGBREAK; } PalEntry *GetPalette() { DBGBREAK; return NULL; } void GetFlashedPalette(PalEntry palette[256]) { DBGBREAK; } void UpdatePalette() { DBGBREAK; } bool SetGamma(float gamma) { Gamma = gamma; return true; } bool SetFlash(PalEntry rgb, int amount) { DBGBREAK; return false; } void GetFlash(PalEntry &rgb, int &amount) { DBGBREAK; } int GetPageCount() { DBGBREAK; return 0; } bool IsFullscreen() { DBGBREAK; return 0; } #ifdef _WIN32 void PaletteChanged() {} int QueryNewPalette() { return 0; } bool Is8BitMode() { return false; } #endif float Gamma; }; class FPaletteTester : public FTexture { public: FPaletteTester (); const uint8_t *GetColumn(unsigned int column, const Span **spans_out); const uint8_t *GetPixels(); bool CheckModified(); void SetTranslation(int num); protected: uint8_t Pixels[16*16]; int CurTranslation; int WantTranslation; static const Span DummySpan[2]; void MakeTexture(); }; const FTexture::Span FPaletteTester::DummySpan[2] = { { 0, 16 }, { 0, 0 } }; int DisplayWidth, DisplayHeight, DisplayBits; FFont *SmallFont, *SmallFont2, *BigFont, *ConFont, *IntermissionFont; uint32_t Col2RGB8[65][256]; uint32_t *Col2RGB8_LessPrecision[65]; uint32_t Col2RGB8_Inverse[65][256]; ColorTable32k RGB32k; ColorTable256k RGB256k; static uint32_t Col2RGB8_2[63][256]; // [RH] The framebuffer is no longer a mere byte array. // There's also only one, not four. DFrameBuffer *screen; CVAR (Int, vid_defwidth, 640, CVAR_ARCHIVE|CVAR_GLOBALCONFIG) CVAR (Int, vid_defheight, 480, CVAR_ARCHIVE|CVAR_GLOBALCONFIG) CVAR (Int, vid_defbits, 8, CVAR_ARCHIVE|CVAR_GLOBALCONFIG) CVAR (Bool, vid_fps, false, 0) CVAR (Bool, ticker, false, 0) CVAR (Int, vid_showpalette, 0, 0) CUSTOM_CVAR (Bool, vid_vsync, false, CVAR_ARCHIVE|CVAR_GLOBALCONFIG) { if (screen != NULL) { screen->SetVSync (*self); } } CUSTOM_CVAR (Int, vid_refreshrate, 0, CVAR_ARCHIVE|CVAR_GLOBALCONFIG) { if (screen != NULL) { screen->NewRefreshRate(); } } CUSTOM_CVAR (Float, dimamount, -1.f, CVAR_ARCHIVE) { if (self < 0.f && self != -1.f) { self = -1.f; } else if (self > 1.f) { self = 1.f; } } CVAR (Color, dimcolor, 0xffd700, CVAR_ARCHIVE) // [RH] Set true when vid_setmode command has been executed bool setmodeneeded = false; // [RH] Resolution to change to when setmodeneeded is true int NewWidth, NewHeight, NewBits; //========================================================================== // // DCanvas Constructor // //========================================================================== DCanvas::DCanvas (int _width, int _height, bool _bgra) { // Init member vars Buffer = NULL; LockCount = 0; Width = _width; Height = _height; Bgra = _bgra; } //========================================================================== // // DCanvas Destructor // //========================================================================== DCanvas::~DCanvas () { } //========================================================================== // // DCanvas :: IsValid // //========================================================================== bool DCanvas::IsValid () { // A nun-subclassed DCanvas is never valid return false; } //========================================================================== // // DCanvas :: FlatFill // // Fill an area with a texture. If local_origin is false, then the origin // used for the wrapping is (0,0). Otherwise, (left,right) is used. // //========================================================================== void DCanvas::FlatFill (int left, int top, int right, int bottom, FTexture *src, bool local_origin) { int w = src->GetWidth(); int h = src->GetHeight(); // Repeatedly draw the texture, left-to-right, top-to-bottom. for (int y = local_origin ? top : (top / h * h); y < bottom; y += h) { for (int x = local_origin ? left : (left / w * w); x < right; x += w) { DrawTexture (src, x, y, DTA_ClipLeft, left, DTA_ClipRight, right, DTA_ClipTop, top, DTA_ClipBottom, bottom, DTA_TopOffset, 0, DTA_LeftOffset, 0, TAG_DONE); } } } //========================================================================== // // DCanvas :: Dim // // Applies a colored overlay to the entire screen, with the opacity // determined by the dimamount cvar. // //========================================================================== void DCanvas::Dim (PalEntry color) { PalEntry dimmer; float amount; if (dimamount >= 0) { dimmer = PalEntry(dimcolor); amount = dimamount; } else { dimmer = gameinfo.dimcolor; amount = gameinfo.dimamount; } if (gameinfo.gametype == GAME_Hexen && gamestate == GS_DEMOSCREEN) { // On the Hexen title screen, the default dimming is not // enough to make the menus readable. amount = MIN (1.f, amount*2.f); } // Add the cvar's dimming on top of the color passed to the function if (color.a != 0) { float dim[4] = { color.r/255.f, color.g/255.f, color.b/255.f, color.a/255.f }; V_AddBlend (dimmer.r/255.f, dimmer.g/255.f, dimmer.b/255.f, amount, dim); dimmer = PalEntry (uint8_t(dim[0]*255), uint8_t(dim[1]*255), uint8_t(dim[2]*255)); amount = dim[3]; } Dim (dimmer, amount, 0, 0, Width, Height); } //========================================================================== // // DCanvas :: GetScreenshotBuffer // // Returns a buffer containing the most recently displayed frame. The // width and height of this buffer are the same as the canvas. // //========================================================================== void DCanvas::GetScreenshotBuffer(const uint8_t *&buffer, int &pitch, ESSType &color_type) { Lock(true); buffer = GetBuffer(); pitch = IsBgra() ? GetPitch() * 4 : GetPitch(); color_type = IsBgra() ? SS_BGRA : SS_PAL; } //========================================================================== // // DCanvas :: ReleaseScreenshotBuffer // // Releases the buffer obtained through GetScreenshotBuffer. These calls // must not be nested. // //========================================================================== void DCanvas::ReleaseScreenshotBuffer() { Unlock(); } //========================================================================== // // V_GetColorFromString // // Passed a string of the form "#RGB", "#RRGGBB", "R G B", or "RR GG BB", // returns a number representing that color. If palette is non-NULL, the // index of the best match in the palette is returned, otherwise the // RRGGBB value is returned directly. // //========================================================================== int V_GetColorFromString (const uint32_t *palette, const char *cstr, FScriptPosition *sc) { int c[3], i, p; char val[3]; val[2] = '\0'; // Check for HTML-style #RRGGBB or #RGB color string if (cstr[0] == '#') { size_t len = strlen (cstr); if (len == 7) { // Extract each eight-bit component into c[]. for (i = 0; i < 3; ++i) { val[0] = cstr[1 + i*2]; val[1] = cstr[2 + i*2]; c[i] = ParseHex (val, sc); } } else if (len == 4) { // Extract each four-bit component into c[], expanding to eight bits. for (i = 0; i < 3; ++i) { val[1] = val[0] = cstr[1 + i]; c[i] = ParseHex (val, sc); } } else { // Bad HTML-style; pretend it's black. c[2] = c[1] = c[0] = 0; } } else { if (strlen(cstr) == 6) { char *p; int color = strtol(cstr, &p, 16); if (*p == 0) { // RRGGBB string c[0] = (color & 0xff0000) >> 16; c[1] = (color & 0xff00) >> 8; c[2] = (color & 0xff); } else goto normal; } else { normal: // Treat it as a space-delimited hexadecimal string for (i = 0; i < 3; ++i) { // Skip leading whitespace while (*cstr <= ' ' && *cstr != '\0') { cstr++; } // Extract a component and convert it to eight-bit for (p = 0; *cstr > ' '; ++p, ++cstr) { if (p < 2) { val[p] = *cstr; } } if (p == 0) { c[i] = 0; } else { if (p == 1) { val[1] = val[0]; } c[i] = ParseHex (val, sc); } } } } if (palette) return ColorMatcher.Pick (c[0], c[1], c[2]); else return MAKERGB(c[0], c[1], c[2]); } //========================================================================== // // V_GetColorStringByName // // Searches for the given color name in x11r6rgb.txt and returns an // HTML-ish "#RRGGBB" string for it if found or the empty string if not. // //========================================================================== FString V_GetColorStringByName (const char *name, FScriptPosition *sc) { FMemLump rgbNames; char *rgbEnd; char *rgb, *endp; int rgblump; int c[3], step; size_t namelen; if (Wads.GetNumLumps()==0) return FString(); rgblump = Wads.CheckNumForName ("X11R6RGB"); if (rgblump == -1) { if (!sc) Printf ("X11R6RGB lump not found\n"); else sc->Message(MSG_WARNING, "X11R6RGB lump not found"); return FString(); } rgbNames = Wads.ReadLump (rgblump); rgb = (char *)rgbNames.GetMem(); rgbEnd = rgb + Wads.LumpLength (rgblump); step = 0; namelen = strlen (name); while (rgb < rgbEnd) { // Skip white space if (*rgb <= ' ') { do { rgb++; } while (rgb < rgbEnd && *rgb <= ' '); } else if (step == 0 && *rgb == '!') { // skip comment lines do { rgb++; } while (rgb < rgbEnd && *rgb != '\n'); } else if (step < 3) { // collect RGB values c[step++] = strtoul (rgb, &endp, 10); if (endp == rgb) { break; } rgb = endp; } else { // Check color name endp = rgb; // Find the end of the line while (endp < rgbEnd && *endp != '\n') endp++; // Back up over any whitespace while (endp > rgb && *endp <= ' ') endp--; if (endp == rgb) { break; } size_t checklen = ++endp - rgb; if (checklen == namelen && strnicmp (rgb, name, checklen) == 0) { FString descr; descr.Format ("#%02x%02x%02x", c[0], c[1], c[2]); return descr; } rgb = endp; step = 0; } } if (rgb < rgbEnd) { if (!sc) Printf ("X11R6RGB lump is corrupt\n"); else sc->Message(MSG_WARNING, "X11R6RGB lump is corrupt"); } return FString(); } //========================================================================== // // V_GetColor // // Works like V_GetColorFromString(), but also understands X11 color names. // //========================================================================== int V_GetColor (const uint32_t *palette, const char *str, FScriptPosition *sc) { FString string = V_GetColorStringByName (str, sc); int res; if (!string.IsEmpty()) { res = V_GetColorFromString (palette, string, sc); } else { res = V_GetColorFromString (palette, str, sc); } return res; } int V_GetColor(const uint32_t *palette, FScanner &sc) { FScriptPosition scc = sc; return V_GetColor(palette, sc.String, &scc); } //========================================================================== // // BuildTransTable // // Build the tables necessary for blending // //========================================================================== static void BuildTransTable (const PalEntry *palette) { int r, g, b; // create the RGB555 lookup table for (r = 0; r < 32; r++) for (g = 0; g < 32; g++) for (b = 0; b < 32; b++) RGB32k.RGB[r][g][b] = ColorMatcher.Pick ((r<<3)|(r>>2), (g<<3)|(g>>2), (b<<3)|(b>>2)); // create the RGB666 lookup table for (r = 0; r < 64; r++) for (g = 0; g < 64; g++) for (b = 0; b < 64; b++) RGB256k.RGB[r][g][b] = ColorMatcher.Pick ((r<<2)|(r>>4), (g<<2)|(g>>4), (b<<2)|(b>>4)); int x, y; // create the swizzled palette for (x = 0; x < 65; x++) for (y = 0; y < 256; y++) Col2RGB8[x][y] = (((palette[y].r*x)>>4)<<20) | ((palette[y].g*x)>>4) | (((palette[y].b*x)>>4)<<10); // create the swizzled palette with the lsb of red and blue forced to 0 // (for green, a 1 is okay since it never gets added into) for (x = 1; x < 64; x++) { Col2RGB8_LessPrecision[x] = Col2RGB8_2[x-1]; for (y = 0; y < 256; y++) { Col2RGB8_2[x-1][y] = Col2RGB8[x][y] & 0x3feffbff; } } Col2RGB8_LessPrecision[0] = Col2RGB8[0]; Col2RGB8_LessPrecision[64] = Col2RGB8[64]; // create the inverse swizzled palette for (x = 0; x < 65; x++) for (y = 0; y < 256; y++) { Col2RGB8_Inverse[x][y] = (((((255-palette[y].r)*x)>>4)<<20) | (((255-palette[y].g)*x)>>4) | ((((255-palette[y].b)*x)>>4)<<10)) & 0x3feffbff; } } //========================================================================== // // DCanvas :: CalcGamma // //========================================================================== void DCanvas::CalcGamma (float gamma, uint8_t gammalookup[256]) { // I found this formula on the web at // , // but that page no longer exits. double invgamma = 1.f / gamma; int i; for (i = 0; i < 256; i++) { gammalookup[i] = (uint8_t)(255.0 * pow (i / 255.0, invgamma) + 0.5); } } //========================================================================== // // DSimpleCanvas Constructor // // A simple canvas just holds a buffer in main memory. // //========================================================================== DSimpleCanvas::DSimpleCanvas (int width, int height, bool bgra) : DCanvas (width, height, bgra) { MemBuffer = nullptr; Resize(width, height); } void DSimpleCanvas::Resize(int width, int height) { Width = width; Height = height; if (MemBuffer != NULL) { delete[] MemBuffer; MemBuffer = NULL; } // Making the pitch a power of 2 is very bad for performance // Try to maximize the number of cache lines that can be filled // for each column drawing operation by making the pitch slightly // longer than the width. The values used here are all based on // empirical evidence. if (width <= 640) { // For low resolutions, just keep the pitch the same as the width. // Some speedup can be seen using the technique below, but the speedup // is so marginal that I don't consider it worthwhile. Pitch = width; } else { // If we couldn't figure out the CPU's L1 cache line size, assume // it's 32 bytes wide. if (CPU.DataL1LineSize == 0) { CPU.DataL1LineSize = 32; } // The Athlon and P3 have very different caches, apparently. // I am going to generalize the Athlon's performance to all AMD // processors and the P3's to all non-AMD processors. I don't know // how smart that is, but I don't have a vast plethora of // processors to test with. if (CPU.bIsAMD) { Pitch = width + CPU.DataL1LineSize; } else { Pitch = width + MAX(0, CPU.DataL1LineSize - 8); } } int bytes_per_pixel = Bgra ? 4 : 1; MemBuffer = new uint8_t[Pitch * height * bytes_per_pixel]; memset (MemBuffer, 0, Pitch * height * bytes_per_pixel); } //========================================================================== // // DSimpleCanvas Destructor // //========================================================================== DSimpleCanvas::~DSimpleCanvas () { if (MemBuffer != NULL) { delete[] MemBuffer; MemBuffer = NULL; } } //========================================================================== // // DSimpleCanvas :: IsValid // //========================================================================== bool DSimpleCanvas::IsValid () { return (MemBuffer != NULL); } //========================================================================== // // DSimpleCanvas :: Lock // //========================================================================== bool DSimpleCanvas::Lock (bool) { if (LockCount == 0) { Buffer = MemBuffer; } LockCount++; return false; // System surfaces are never lost } //========================================================================== // // DSimpleCanvas :: Unlock // //========================================================================== void DSimpleCanvas::Unlock () { if (--LockCount <= 0) { LockCount = 0; Buffer = NULL; // Enforce buffer access only between Lock/Unlock } } //========================================================================== // // DFrameBuffer Constructor // // A frame buffer canvas is the most common and represents the image that // gets drawn to the screen. // //========================================================================== DFrameBuffer::DFrameBuffer (int width, int height, bool bgra) : DSimpleCanvas (width, height, bgra) { LastMS = LastSec = FrameCount = LastCount = LastTic = 0; Accel2D = false; VideoWidth = width; VideoHeight = height; } //========================================================================== // // DFrameBuffer :: PostprocessBgra // // Copies data to destination buffer while performing gamma and flash. // This is only needed if a target cannot do this with shaders. // //========================================================================== void DFrameBuffer::CopyWithGammaBgra(void *output, int pitch, const uint8_t *gammared, const uint8_t *gammagreen, const uint8_t *gammablue, PalEntry flash, int flash_amount) { const uint8_t *gammatables[3] = { gammared, gammagreen, gammablue }; if (flash_amount > 0) { uint16_t inv_flash_amount = 256 - flash_amount; uint16_t flash_red = flash.r * flash_amount; uint16_t flash_green = flash.g * flash_amount; uint16_t flash_blue = flash.b * flash_amount; for (int y = 0; y < Height; y++) { uint8_t *dest = (uint8_t*)output + y * pitch; uint8_t *src = MemBuffer + y * Pitch * 4; for (int x = 0; x < Width; x++) { uint16_t fg_red = src[2]; uint16_t fg_green = src[1]; uint16_t fg_blue = src[0]; uint16_t red = (fg_red * inv_flash_amount + flash_red) >> 8; uint16_t green = (fg_green * inv_flash_amount + flash_green) >> 8; uint16_t blue = (fg_blue * inv_flash_amount + flash_blue) >> 8; dest[0] = gammatables[2][blue]; dest[1] = gammatables[1][green]; dest[2] = gammatables[0][red]; dest[3] = 0xff; dest += 4; src += 4; } } } else { for (int y = 0; y < Height; y++) { uint8_t *dest = (uint8_t*)output + y * pitch; uint8_t *src = MemBuffer + y * Pitch * 4; for (int x = 0; x < Width; x++) { dest[0] = gammatables[2][src[0]]; dest[1] = gammatables[1][src[1]]; dest[2] = gammatables[0][src[2]]; dest[3] = 0xff; dest += 4; src += 4; } } } } //========================================================================== // // DFrameBuffer :: DrawRateStuff // // Draws the fps counter, dot ticker, and palette debug. // //========================================================================== void DFrameBuffer::DrawRateStuff () { // Draws frame time and cumulative fps if (vid_fps) { uint32_t ms = I_FPSTime(); uint32_t howlong = ms - LastMS; if ((signed)howlong >= 0) { char fpsbuff[40]; int chars; int rate_x; int textScale = active_con_scale(); chars = mysnprintf (fpsbuff, countof(fpsbuff), "%2u ms (%3u fps)", howlong, LastCount); rate_x = Width / textScale - ConFont->StringWidth(&fpsbuff[0]); Clear (rate_x * textScale, 0, Width, ConFont->GetHeight() * textScale, GPalette.BlackIndex, 0); DrawText (ConFont, CR_WHITE, rate_x, 0, (char *)&fpsbuff[0], DTA_VirtualWidth, screen->GetWidth() / textScale, DTA_VirtualHeight, screen->GetHeight() / textScale, DTA_KeepRatio, true, TAG_DONE); uint32_t thisSec = ms/1000; if (LastSec < thisSec) { LastCount = FrameCount / (thisSec - LastSec); LastSec = thisSec; FrameCount = 0; } FrameCount++; } LastMS = ms; } // draws little dots on the bottom of the screen if (ticker) { int i = I_GetTime(false); int tics = i - LastTic; uint8_t *buffer = GetBuffer(); LastTic = i; if (tics > 20) tics = 20; // Buffer can be NULL if we're doing hardware accelerated 2D if (buffer != NULL) { if (IsBgra()) { uint32_t *buffer32 = (uint32_t*)buffer; buffer32 += (GetHeight() - 1) * GetPitch(); for (i = 0; i < tics * 2; i += 2) buffer32[i] = 0xffffffff; for (; i < 20 * 2; i += 2) buffer32[i] = 0xff000000; } else { buffer += (GetHeight() - 1) * GetPitch(); for (i = 0; i < tics * 2; i += 2) buffer[i] = 0xff; for (; i < 20 * 2; i += 2) buffer[i] = 0x00; } } else { for (i = 0; i < tics*2; i += 2) Clear(i, Height-1, i+1, Height, 255, 0); for ( ; i < 20*2; i += 2) Clear(i, Height-1, i+1, Height, 0, 0); } } // draws the palette for debugging if (vid_showpalette) { // This used to just write the palette to the display buffer. // With hardware-accelerated 2D, that doesn't work anymore. // Drawing it as a texture does and continues to show how // well the PalTex shader is working. static FPaletteTester palette; int size = screen->GetHeight() < 800 ? 16 * 7 : 16 * 7 * 2; palette.SetTranslation(vid_showpalette); DrawTexture(&palette, 0, 0, DTA_DestWidth, size, DTA_DestHeight, size, DTA_Masked, false, TAG_DONE); } } //========================================================================== // // FPaleteTester Constructor // // This is just a 16x16 image with every possible color value. // //========================================================================== FPaletteTester::FPaletteTester() { Width = 16; Height = 16; WidthBits = 4; HeightBits = 4; WidthMask = 15; CurTranslation = 0; WantTranslation = 1; MakeTexture(); } //========================================================================== // // FPaletteTester :: CheckModified // //========================================================================== bool FPaletteTester::CheckModified() { return CurTranslation != WantTranslation; } //========================================================================== // // FPaletteTester :: SetTranslation // //========================================================================== void FPaletteTester::SetTranslation(int num) { if (num >= 1 && num <= 9) { WantTranslation = num; } } //========================================================================== // // FPaletteTester :: GetColumn // //========================================================================== const uint8_t *FPaletteTester::GetColumn (unsigned int column, const Span **spans_out) { if (CurTranslation != WantTranslation) { MakeTexture(); } column &= 15; if (spans_out != NULL) { *spans_out = DummySpan; } return Pixels + column*16; } //========================================================================== // // FPaletteTester :: GetPixels // //========================================================================== const uint8_t *FPaletteTester::GetPixels () { if (CurTranslation != WantTranslation) { MakeTexture(); } return Pixels; } //========================================================================== // // FPaletteTester :: MakeTexture // //========================================================================== void FPaletteTester::MakeTexture() { int i, j, k, t; uint8_t *p; t = WantTranslation; p = Pixels; k = 0; for (i = 0; i < 16; ++i) { for (j = 0; j < 16; ++j) { *p++ = (t > 1) ? translationtables[TRANSLATION_Standard][t - 2]->Remap[k] : k; k += 16; } k -= 255; } CurTranslation = t; } //========================================================================== // // DFrameBuffer :: CopyFromBuff // // Copies pixels from main memory to video memory. This is only used by // DDrawFB. // //========================================================================== void DFrameBuffer::CopyFromBuff (uint8_t *src, int srcPitch, int width, int height, uint8_t *dest) { if (Pitch == width && Pitch == Width && srcPitch == width) { memcpy (dest, src, Width * Height); } else { for (int y = 0; y < height; y++) { memcpy (dest, src, width); dest += Pitch; src += srcPitch; } } } //========================================================================== // // DFrameBuffer :: SetVSync // // Turns vertical sync on and off, if supported. // //========================================================================== void DFrameBuffer::SetVSync (bool vsync) { } //========================================================================== // // DFrameBuffer :: NewRefreshRate // // Sets the fullscreen display to the new refresh rate in vid_refreshrate, // if possible. // //========================================================================== void DFrameBuffer::NewRefreshRate () { } //========================================================================== // // DFrameBuffer :: SetBlendingRect // // Defines the area of the screen containing the 3D view. // //========================================================================== void DFrameBuffer::SetBlendingRect (int x1, int y1, int x2, int y2) { } //========================================================================== // // DFrameBuffer :: Begin2D // // Signal that 3D rendering is complete, and the rest of the operations on // the canvas until Unlock() will be 2D ones. // //========================================================================== bool DFrameBuffer::Begin2D (bool copy3d) { isIn2D = true; ClearClipRect(); return false; } //========================================================================== // // DFrameBuffer :: DrawBlendingRect // // In hardware 2D modes, the blending rect needs to be drawn separately // from transferring the 3D scene to video memory, because the weapon // sprite is drawn on top of that. // //========================================================================== void DFrameBuffer::DrawBlendingRect() { } //========================================================================== // // DFrameBuffer :: CreateTexture // // Creates a native texture for a game texture, if supported. // //========================================================================== FNativeTexture *DFrameBuffer::CreateTexture(FTexture *gametex, bool wrapping) { return NULL; } //========================================================================== // // DFrameBuffer :: CreatePalette // // Creates a native palette from a remap table, if supported. // //========================================================================== FNativePalette *DFrameBuffer::CreatePalette(FRemapTable *remap) { return NULL; } //========================================================================== // // DFrameBuffer :: WipeStartScreen // // Grabs a copy of the screen currently displayed to serve as the initial // frame of a screen wipe. Also determines which screenwipe will be // performed. // //========================================================================== bool DFrameBuffer::WipeStartScreen(int type) { return wipe_StartScreen(type); } //========================================================================== // // DFrameBuffer :: WipeEndScreen // // Grabs a copy of the most-recently drawn, but not yet displayed, screen // to serve as the final frame of a screen wipe. // //========================================================================== void DFrameBuffer::WipeEndScreen() { wipe_EndScreen(); Unlock(); } //========================================================================== // // DFrameBuffer :: WipeDo // // Draws one frame of a screenwipe. Should be called no more than 35 // times per second. If called less than that, ticks indicates how many // ticks have passed since the last call. // //========================================================================== bool DFrameBuffer::WipeDo(int ticks) { Lock(true); return wipe_ScreenWipe(ticks); } //========================================================================== // // DFrameBuffer :: WipeCleanup // //========================================================================== void DFrameBuffer::WipeCleanup() { wipe_Cleanup(); } //========================================================================== // // DFrameBuffer :: GameRestart // //========================================================================== void DFrameBuffer::GameRestart() { } //=========================================================================== // // // //=========================================================================== FNativePalette::~FNativePalette() { } FNativeTexture::~FNativeTexture() { } bool FNativeTexture::CheckWrapping(bool wrapping) { return true; } CCMD(clean) { Printf ("CleanXfac: %d\nCleanYfac: %d\n", CleanXfac, CleanYfac); } // // V_SetResolution // bool V_DoModeSetup (int width, int height, int bits) { DFrameBuffer *buff = I_SetMode (width, height, screen); if (buff == NULL) { return false; } screen = buff; screen->SetGamma (Gamma); // Load fonts now so they can be packed into textures straight away, // if D3DFB is being used for the display. FFont::StaticPreloadFonts(); DisplayBits = bits; V_UpdateModeSize(width, height); M_RefreshModesList (); return true; } void V_UpdateModeSize (int width, int height) { int cx1, cx2; V_CalcCleanFacs(320, 200, width, height, &CleanXfac, &CleanYfac, &cx1, &cx2); CleanWidth = width / CleanXfac; CleanHeight = height / CleanYfac; assert(CleanWidth >= 320); assert(CleanHeight >= 200); if (width < 800 || width >= 960) { if (cx1 < cx2) { // Special case in which we don't need to scale down. CleanXfac_1 = CleanYfac_1 = cx1; } else { CleanXfac_1 = MAX(CleanXfac - 1, 1); CleanYfac_1 = MAX(CleanYfac - 1, 1); // On larger screens this is not enough so make sure it's at most 3/4 of the screen's width while (CleanXfac_1 * 320 > screen->GetWidth()*3/4 && CleanXfac_1 > 2) { CleanXfac_1--; CleanYfac_1--; } } CleanWidth_1 = width / CleanXfac_1; CleanHeight_1 = height / CleanYfac_1; } else // if the width is between 800 and 960 the ratio between the screensize and CleanXFac-1 becomes too large. { CleanXfac_1 = CleanXfac; CleanYfac_1 = CleanYfac; CleanWidth_1 = CleanWidth; CleanHeight_1 = CleanHeight; } DisplayWidth = width; DisplayHeight = height; R_OldBlend = ~0; Renderer->OnModeSet(); } void V_OutputResized (int width, int height) { V_UpdateModeSize(width, height); setsizeneeded = true; if (StatusBar != NULL) { StatusBar->CallScreenSizeChanged(); } C_NewModeAdjust(); } void V_CalcCleanFacs (int designwidth, int designheight, int realwidth, int realheight, int *cleanx, int *cleany, int *_cx1, int *_cx2) { float ratio; int cwidth; int cheight; int cx1, cy1, cx2, cy2; // For larger screems always use at least a 16:9 ratio for clean factor calculation, even if the actual ratio is narrower. if (realwidth > 1280 && (double)realwidth / realheight < 16./9) { realheight = realwidth * 9 / 16; } ratio = ActiveRatio(realwidth, realheight); if (AspectTallerThanWide(ratio)) { cwidth = realwidth; cheight = realheight * AspectMultiplier(ratio) / 48; } else { cwidth = realwidth * AspectMultiplier(ratio) / 48; cheight = realheight; } // Use whichever pair of cwidth/cheight or width/height that produces less difference // between CleanXfac and CleanYfac. cx1 = MAX(cwidth / designwidth, 1); cy1 = MAX(cheight / designheight, 1); cx2 = MAX(realwidth / designwidth, 1); cy2 = MAX(realheight / designheight, 1); if (abs(cx1 - cy1) <= abs(cx2 - cy2) || MAX(cx1, cx2) >= 4) { // e.g. 640x360 looks better with this. *cleanx = cx1; *cleany = cy1; } else { // e.g. 720x480 looks better with this. *cleanx = cx2; *cleany = cy2; } if (*cleanx < *cleany) *cleany = *cleanx; else *cleanx = *cleany; if (_cx1 != NULL) *_cx1 = cx1; if (_cx2 != NULL) *_cx2 = cx2; } bool IVideo::SetResolution (int width, int height, int bits) { int oldwidth, oldheight; int oldbits; if (screen) { oldwidth = SCREENWIDTH; oldheight = SCREENHEIGHT; oldbits = DisplayBits; } else { // Harmless if screen wasn't allocated oldwidth = width; oldheight = height; oldbits = bits; } I_ClosestResolution (&width, &height, bits); if (!I_CheckResolution (width, height, bits)) { // Try specified resolution if (!I_CheckResolution (oldwidth, oldheight, oldbits)) { // Try previous resolution (if any) return false; } else { width = oldwidth; height = oldheight; bits = oldbits; } } return V_DoModeSetup (width, height, bits); } CCMD (vid_setmode) { bool goodmode = false; int width = 0, height = SCREENHEIGHT; int bits = DisplayBits; if (argv.argc() > 1) { width = atoi (argv[1]); if (argv.argc() > 2) { height = atoi (argv[2]); if (argv.argc() > 3) { bits = atoi (argv[3]); } } } if (width && I_CheckResolution (width, height, bits)) { goodmode = true; } if (!fullscreen) goodmode = true; if (goodmode) { // The actual change of resolution will take place // near the beginning of D_Display(). if (gamestate != GS_STARTUP) { setmodeneeded = true; NewWidth = width; NewHeight = height; NewBits = bits; } } else if (width) { Printf ("Unknown resolution %d x %d x %d\n", width, height, bits); } else { Printf ("Usage: vid_setmode \n"); } } // // V_Init // void V_Init (bool restart) { const char *i; int width, height, bits; atterm (V_Shutdown); // [RH] Initialize palette management InitPalette (); if (!restart) { width = height = bits = 0; if ( (i = Args->CheckValue ("-width")) ) width = atoi (i); if ( (i = Args->CheckValue ("-height")) ) height = atoi (i); if ( (i = Args->CheckValue ("-bits")) ) bits = atoi (i); if (width == 0) { if (height == 0) { width = vid_defwidth; height = vid_defheight; } else { width = (height * 8) / 6; } } else if (height == 0) { height = (width * 6) / 8; } if (bits == 0) { bits = vid_defbits; } screen = new DDummyFrameBuffer (width, height); } // Update screen palette when restarting else { PalEntry *palette = screen->GetPalette (); for (int i = 0; i < 256; ++i) *palette++ = GPalette.BaseColors[i]; screen->UpdatePalette(); } BuildTransTable (GPalette.BaseColors); } void V_Init2() { int width = screen->GetWidth(); int height = screen->GetHeight(); float gamma = static_cast(screen)->Gamma; { DFrameBuffer *s = screen; screen = NULL; delete s; } I_InitGraphics(); I_ClosestResolution (&width, &height, 8); if (!Video->SetResolution (width, height, 8)) I_FatalError ("Could not set resolution to %d x %d x %d", width, height, 8); else Printf ("Resolution: %d x %d\n", SCREENWIDTH, SCREENHEIGHT); screen->SetGamma (gamma); Renderer->RemapVoxels(); FBaseCVar::ResetColors (); C_NewModeAdjust(); M_InitVideoModesMenu(); V_SetBorderNeedRefresh(); setsizeneeded = true; } void V_Shutdown() { if (screen) { DFrameBuffer *s = screen; screen = NULL; delete s; } V_ClearFonts(); } EXTERN_CVAR (Bool, vid_tft) CUSTOM_CVAR (Bool, vid_nowidescreen, false, CVAR_GLOBALCONFIG|CVAR_ARCHIVE) { setsizeneeded = true; if (StatusBar != NULL) { StatusBar->CallScreenSizeChanged(); } } CUSTOM_CVAR (Int, vid_aspect, 0, CVAR_GLOBALCONFIG|CVAR_ARCHIVE) { setsizeneeded = true; if (StatusBar != NULL) { StatusBar->CallScreenSizeChanged(); } } // Helper for ActiveRatio and CheckRatio. Returns the forced ratio type, or -1 if none. int ActiveFakeRatio(int width, int height) { int fakeratio = -1; if ((vid_aspect >= 1) && (vid_aspect <= 6)) { // [SP] User wants to force aspect ratio; let them. fakeratio = int(vid_aspect); if (fakeratio == 3) { fakeratio = 0; } else if (fakeratio == 5) { fakeratio = 3; } } if (vid_nowidescreen) { if (!vid_tft) { fakeratio = 0; } else { fakeratio = (height * 5 / 4 == width) ? 4 : 0; } } return fakeratio; } // Active screen ratio based on cvars and size float ActiveRatio(int width, int height, float *trueratio) { static float forcedRatioTypes[] = { 4 / 3.0f, 16 / 9.0f, 16 / 10.0f, 17 / 10.0f, 5 / 4.0f, 17 / 10.0f, 21 / 9.0f }; float ratio = width / (float)height; int fakeratio = ActiveFakeRatio(width, height); if (trueratio) *trueratio = ratio; return (fakeratio != -1) ? forcedRatioTypes[fakeratio] : ratio; } DEFINE_ACTION_FUNCTION(_Screen, GetAspectRatio) { ACTION_RETURN_FLOAT(ActiveRatio(screen->GetWidth(), screen->GetHeight(), nullptr)); } // Tries to guess the physical dimensions of the screen based on the // screen's pixel dimensions. Can return: // 0: 4:3 // 1: 16:9 // 2: 16:10 // 3: 17:10 // 4: 5:4 // 5: 17:10 (redundant, never returned) // 6: 21:9 int CheckRatio (int width, int height, int *trueratio) { float aspect = width / (float)height; static std::pair ratioTypes[] = { { 21 / 9.0f , 6 }, { 16 / 9.0f , 1 }, { 17 / 10.0f , 3 }, { 16 / 10.0f , 2 }, { 4 / 3.0f , 0 }, { 5 / 4.0f , 4 }, { 0.0f, 0 } }; int ratio = ratioTypes[0].second; float distance = fabs(ratioTypes[0].first - aspect); for (int i = 1; ratioTypes[i].first != 0.0f; i++) { float d = fabs(ratioTypes[i].first - aspect); if (d < distance) { ratio = ratioTypes[i].second; distance = d; } } int fakeratio = ActiveFakeRatio(width, height); if (fakeratio == -1) fakeratio = ratio; if (trueratio) *trueratio = ratio; return fakeratio; } int AspectBaseWidth(float aspect) { return (int)round(240.0f * aspect * 3.0f); } int AspectBaseHeight(float aspect) { if (!AspectTallerThanWide(aspect)) return (int)round(200.0f * (320.0f / (AspectBaseWidth(aspect) / 3.0f)) * 3.0f); else return (int)round((200.0f * (4.0f / 3.0f)) / aspect * 3.0f); } double AspectPspriteOffset(float aspect) { if (!AspectTallerThanWide(aspect)) return 0.0; else return ((4.0 / 3.0) / aspect - 1.0) * 97.5; } int AspectMultiplier(float aspect) { if (!AspectTallerThanWide(aspect)) return (int)round(320.0f / (AspectBaseWidth(aspect) / 3.0f) * 48.0f); else return (int)round(200.0f / (AspectBaseHeight(aspect) / 3.0f) * 48.0f); } bool AspectTallerThanWide(float aspect) { return aspect < 1.333f; } void IVideo::DumpAdapters () { Printf("Multi-monitor support unavailable.\n"); } CCMD(vid_listadapters) { if (Video != NULL) Video->DumpAdapters(); } DEFINE_GLOBAL(SmallFont) DEFINE_GLOBAL(SmallFont2) DEFINE_GLOBAL(BigFont) DEFINE_GLOBAL(ConFont) DEFINE_GLOBAL(IntermissionFont) DEFINE_GLOBAL(CleanXfac) DEFINE_GLOBAL(CleanYfac) DEFINE_GLOBAL(CleanWidth) DEFINE_GLOBAL(CleanHeight) DEFINE_GLOBAL(CleanXfac_1) DEFINE_GLOBAL(CleanYfac_1) DEFINE_GLOBAL(CleanWidth_1) DEFINE_GLOBAL(CleanHeight_1)