// SONIC ROBO BLAST 2 //----------------------------------------------------------------------------- // Copyright (C) 1993-1996 by id Software, Inc. // Copyright (C) 1998-2000 by DooM Legacy Team. // Copyright (C) 1999-2018 by Sonic Team Junior. // // This program is free software distributed under the // terms of the GNU General Public License, version 2. // See the 'LICENSE' file for more details. //----------------------------------------------------------------------------- /// \file r_data.c /// \brief Preparation of data for rendering,generation of lookups, caching, retrieval by name #include "doomdef.h" #include "g_game.h" #include "i_video.h" #include "r_local.h" #include "r_sky.h" #include "p_local.h" #include "m_misc.h" #include "r_data.h" #include "w_wad.h" #include "z_zone.h" #include "p_setup.h" // levelflats #include "v_video.h" // pLocalPalette #include "dehacked.h" #if defined (_WIN32) || defined (_WIN32_WCE) #include // alloca(sizeof) #endif #if defined(_MSC_VER) #pragma pack(1) #endif // Not sure if this is necessary, but it was in w_wad.c, so I'm putting it here too -Shadow Hog #ifdef _WIN32_WCE #define AVOID_ERRNO #else #include #endif // // Texture definition. // Each texture is composed of one or more patches, // with patches being lumps stored in the WAD. // The lumps are referenced by number, and patched // into the rectangular texture space using origin // and possibly other attributes. // typedef struct { INT16 originx, originy; INT16 patch, stepdir, colormap; } ATTRPACK mappatch_t; // // Texture definition. // An SRB2 wall texture is a list of patches // which are to be combined in a predefined order. // typedef struct { char name[8]; INT32 masked; INT16 width; INT16 height; INT32 columndirectory; // FIXTHIS: OBSOLETE INT16 patchcount; mappatch_t patches[1]; } ATTRPACK maptexture_t; #if defined(_MSC_VER) #pragma pack() #endif // Store lists of lumps for F_START/F_END etc. typedef struct { UINT16 wadfile; UINT16 firstlump; size_t numlumps; } lumplist_t; // // Graphics. // SRB2 graphics for walls and sprites // is stored in vertical runs of opaque pixels (posts). // A column is composed of zero or more posts, // a patch or sprite is composed of zero or more columns. // size_t numspritelumps, max_spritelumps; // textures INT32 numtextures = 0; // total number of textures found, // size of following tables texture_t **textures = NULL; static UINT32 **texturecolumnofs; // column offset lookup table for each texture static UINT8 **texturecache; // graphics data for each generated full-size texture // texture width is a power of 2, so it can easily repeat along sidedefs using a simple mask INT32 *texturewidthmask; fixed_t *textureheight; // needed for texture pegging INT32 *texturetranslation; // needed for pre rendering sprcache_t *spritecachedinfo; lighttable_t *colormaps; UINT8 *encoremap; #ifdef HASINVERT UINT8 invertmap[256]; #endif // for debugging/info purposes static size_t flatmemory, spritememory, texturememory; // highcolor stuff INT16 color8to16[256]; // remap color index to highcolor rgb value INT16 *hicolormaps; // test a 32k colormap remaps high -> high // Painfully simple texture id cacheing to make maps load faster. :3 static struct { char name[9]; INT32 id; } *tidcache = NULL; static INT32 tidcachelen = 0; // // MAPTEXTURE_T CACHING // When a texture is first needed, it counts the number of composite columns // required in the texture and allocates space for a column directory and // any new columns. // The directory will simply point inside other patches if there is only one // patch in a given column, but any columns with multiple patches will have // new column_ts generated. // // // R_DrawColumnInCache // Clip and draw a column from a patch into a cached post. // static inline void R_DrawColumnInCache(column_t *patch, UINT8 *cache, INT32 originy, INT32 cacheheight) { INT32 count, position; UINT8 *source; INT32 topdelta, prevdelta = -1; while (patch->topdelta != 0xff) { topdelta = patch->topdelta; if (topdelta <= prevdelta) topdelta += prevdelta; prevdelta = topdelta; source = (UINT8 *)patch + 3; count = patch->length; position = originy + topdelta; if (position < 0) { count += position; position = 0; } if (position + count > cacheheight) count = cacheheight - position; if (count > 0) M_Memcpy(cache + position, source, count); patch = (column_t *)((UINT8 *)patch + patch->length + 4); } } // // R_GenerateTexture // // Allocate space for full size texture, either single patch or 'composite' // Build the full textures from patches. // The texture caching system is a little more hungry of memory, but has // been simplified for the sake of highcolor, dynamic ligthing, & speed. // // This is not optimised, but it's supposed to be executed only once // per level, when enough memory is available. // static UINT8 *R_GenerateTexture(size_t texnum) { UINT8 *block; UINT8 *blocktex; texture_t *texture; texpatch_t *patch; patch_t *realpatch; int x, x1, x2, i; size_t blocksize; column_t *patchcol; UINT8 *colofs; I_Assert(texnum <= (size_t)numtextures); texture = textures[texnum]; I_Assert(texture != NULL); // allocate texture column offset lookup // single-patch textures can have holes in them and may be used on // 2sided lines so they need to be kept in 'packed' format // BUT this is wrong for skies and walls with over 255 pixels, // so check if there's holes and if not strip the posts. if (texture->patchcount == 1) { boolean holey = false; patch = texture->patches; realpatch = W_CacheLumpNumPwad(patch->wad, patch->lump, PU_CACHE); // Check the patch for holes. if (texture->width > SHORT(realpatch->width) || texture->height > SHORT(realpatch->height)) holey = true; colofs = (UINT8 *)realpatch->columnofs; for (x = 0; x < texture->width && !holey; x++) { column_t *col = (column_t *)((UINT8 *)realpatch + LONG(*(UINT32 *)&colofs[x<<2])); INT32 topdelta, prevdelta = -1, y = 0; while (col->topdelta != 0xff) { topdelta = col->topdelta; if (topdelta <= prevdelta) topdelta += prevdelta; prevdelta = topdelta; if (topdelta > y) break; y = topdelta + col->length + 1; col = (column_t *)((UINT8 *)col + col->length + 4); } if (y < texture->height) holey = true; // this texture is HOLEy! D: } // If the patch uses transparency, we have to save it this way. if (holey) { texture->holes = true; blocksize = W_LumpLengthPwad(patch->wad, patch->lump); block = Z_Calloc(blocksize, PU_STATIC, // will change tag at end of this function &texturecache[texnum]); M_Memcpy(block, realpatch, blocksize); texturememory += blocksize; // use the patch's column lookup colofs = (block + 8); texturecolumnofs[texnum] = (UINT32 *)colofs; blocktex = block; for (x = 0; x < texture->width; x++) *(UINT32 *)&colofs[x<<2] = LONG(LONG(*(UINT32 *)&colofs[x<<2]) + 3); goto done; } // Otherwise, do multipatch format. } // multi-patch textures (or 'composite') texture->holes = false; blocksize = (texture->width * 4) + (texture->width * texture->height); texturememory += blocksize; block = Z_Malloc(blocksize+1, PU_STATIC, &texturecache[texnum]); memset(block, 0xF7, blocksize+1); // Transparency hack // columns lookup table colofs = block; texturecolumnofs[texnum] = (UINT32 *)colofs; // texture data after the lookup table blocktex = block + (texture->width*4); // Composite the columns together. for (i = 0, patch = texture->patches; i < texture->patchcount; i++, patch++) { realpatch = W_CacheLumpNumPwad(patch->wad, patch->lump, PU_CACHE); x1 = patch->originx; x2 = x1 + SHORT(realpatch->width); if (x1 < 0) x = 0; else x = x1; if (x2 > texture->width) x2 = texture->width; for (; x < x2; x++) { patchcol = (column_t *)((UINT8 *)realpatch + LONG(realpatch->columnofs[x-x1])); // generate column ofset lookup *(UINT32 *)&colofs[x<<2] = LONG((x * texture->height) + (texture->width*4)); R_DrawColumnInCache(patchcol, block + LONG(*(UINT32 *)&colofs[x<<2]), patch->originy, texture->height); } } done: // Now that the texture has been built in column cache, it is purgable from zone memory. Z_ChangeTag(block, PU_CACHE); return blocktex; } // // R_GetTextureNum // // Returns the actual texture id that we should use. // This can either be texnum, the current frame for texnum's anim (if animated), // or 0 if not valid. // INT32 R_GetTextureNum(INT32 texnum) { if (texnum < 0 || texnum >= numtextures) return 0; return texturetranslation[texnum]; } // // R_CheckTextureCache // // Use this if you need to make sure the texture is cached before R_GetColumn calls // e.g.: midtextures and FOF walls // void R_CheckTextureCache(INT32 tex) { if (!texturecache[tex]) R_GenerateTexture(tex); } // // R_GetColumn // UINT8 *R_GetColumn(fixed_t tex, INT32 col) { UINT8 *data; col &= texturewidthmask[tex]; data = texturecache[tex]; if (!data) data = R_GenerateTexture(tex); return data + LONG(texturecolumnofs[tex][col]); } // convert flats to hicolor as they are requested // UINT8 *R_GetFlat(lumpnum_t flatlumpnum) { return W_CacheLumpNum(flatlumpnum, PU_CACHE); } // // Empty the texture cache (used for load wad at runtime) // void R_FlushTextureCache(void) { INT32 i; if (numtextures) for (i = 0; i < numtextures; i++) Z_Free(texturecache[i]); } // Need these prototypes for later; defining them here instead of r_data.h so they're "private" int R_CountTexturesInTEXTURESLump(UINT16 wadNum, UINT16 lumpNum); void R_ParseTEXTURESLump(UINT16 wadNum, UINT16 lumpNum, INT32 *index); // // R_LoadTextures // Initializes the texture list with the textures from the world map. // #define TX_START "TX_START" #define TX_END "TX_END" void R_LoadTextures(void) { INT32 i, k, w; UINT16 j; UINT16 texstart, texend, texturesLumpPos; patch_t *patchlump; texpatch_t *patch; texture_t *texture; // Free previous memory before numtextures change. if (numtextures) { for (i = 0; i < numtextures; i++) { Z_Free(textures[i]); Z_Free(texturecache[i]); } Z_Free(texturetranslation); Z_Free(textures); } // Load patches and textures. // Get the number of textures to check. // NOTE: Make SURE the system does not process // the markers. // This system will allocate memory for all duplicate/patched textures even if it never uses them, // but the alternative is to spend a ton of time checking and re-checking all previous entries just to skip any potentially patched textures. for (w = 0, numtextures = 0; w < numwadfiles; w++) { if (wadfiles[w]->type == RET_PK3) { texstart = W_CheckNumForFolderStartPK3("textures/", (UINT16)w, 0); texend = W_CheckNumForFolderEndPK3("textures/", (UINT16)w, texstart); } else { texstart = W_CheckNumForNamePwad(TX_START, (UINT16)w, 0) + 1; texend = W_CheckNumForNamePwad(TX_END, (UINT16)w, 0); } texturesLumpPos = W_CheckNumForNamePwad("TEXTURES", (UINT16)w, 0); while (texturesLumpPos != INT16_MAX) { numtextures += R_CountTexturesInTEXTURESLump((UINT16)w, (UINT16)texturesLumpPos); texturesLumpPos = W_CheckNumForNamePwad("TEXTURES", (UINT16)w, texturesLumpPos + 1); } // Add all the textures between TX_START and TX_END if (texstart != INT16_MAX && texend != INT16_MAX) { numtextures += (UINT32)(texend - texstart); } // If no textures found by this point, bomb out if (!numtextures && w == (numwadfiles - 1)) { I_Error("No textures detected in any WADs!\n"); } } // Allocate memory and initialize to 0 for all the textures we are initialising. // There are actually 5 buffers allocated in one for convenience. textures = Z_Calloc((numtextures * sizeof(void *)) * 5, PU_STATIC, NULL); // Allocate texture column offset table. texturecolumnofs = (void *)((UINT8 *)textures + (numtextures * sizeof(void *))); // Allocate texture referencing cache. texturecache = (void *)((UINT8 *)textures + ((numtextures * sizeof(void *)) * 2)); // Allocate texture width mask table. texturewidthmask = (void *)((UINT8 *)textures + ((numtextures * sizeof(void *)) * 3)); // Allocate texture height mask table. textureheight = (void *)((UINT8 *)textures + ((numtextures * sizeof(void *)) * 4)); // Create translation table for global animation. texturetranslation = Z_Malloc((numtextures + 1) * sizeof(*texturetranslation), PU_STATIC, NULL); for (i = 0; i < numtextures; i++) texturetranslation[i] = i; for (i = 0, w = 0; w < numwadfiles; w++) { // Get the lump numbers for the markers in the WAD, if they exist. if (wadfiles[w]->type == RET_PK3) { texstart = W_CheckNumForFolderStartPK3("textures/", (UINT16)w, 0); texend = W_CheckNumForFolderEndPK3("textures/", (UINT16)w, texstart); texturesLumpPos = W_CheckNumForNamePwad("TEXTURES", (UINT16)w, 0); while (texturesLumpPos != INT16_MAX) { R_ParseTEXTURESLump(w, texturesLumpPos, &i); texturesLumpPos = W_CheckNumForNamePwad("TEXTURES", (UINT16)w, texturesLumpPos + 1); } } else { texstart = W_CheckNumForNamePwad(TX_START, (UINT16)w, 0) + 1; texend = W_CheckNumForNamePwad(TX_END, (UINT16)w, 0); texturesLumpPos = W_CheckNumForNamePwad("TEXTURES", (UINT16)w, 0); if (texturesLumpPos != INT16_MAX) R_ParseTEXTURESLump(w, texturesLumpPos, &i); } if (texstart == INT16_MAX || texend == INT16_MAX) continue; // Work through each lump between the markers in the WAD. for (j = 0; j < (texend - texstart); i++, j++) { patchlump = W_CacheLumpNumPwad((UINT16)w, texstart + j, PU_CACHE); // Then, check the lump directly to see if it's a texture SOC, // and if it is, load it using dehacked instead. if (strstr((const char *)patchlump, "TEXTURE")) { CONS_Alert(CONS_WARNING, "%s is a Texture SOC.\n", W_CheckNameForNumPwad((UINT16)w,texstart+j)); Z_Unlock(patchlump); DEH_LoadDehackedLumpPwad((UINT16)w, texstart + j); } else { //CONS_Printf("\n\"%s\" is a single patch, dimensions %d x %d",W_CheckNameForNumPwad((UINT16)w,texstart+j),patchlump->width, patchlump->height); texture = textures[i] = Z_Calloc(sizeof(texture_t) + sizeof(texpatch_t), PU_STATIC, NULL); // Set texture properties. M_Memcpy(texture->name, W_CheckNameForNumPwad((UINT16)w, texstart + j), sizeof(texture->name)); texture->width = SHORT(patchlump->width); texture->height = SHORT(patchlump->height); texture->patchcount = 1; texture->holes = false; // Allocate information for the texture's patches. patch = &texture->patches[0]; patch->originx = patch->originy = 0; patch->wad = (UINT16)w; patch->lump = texstart + j; Z_Unlock(patchlump); k = 1; while (k << 1 <= texture->width) k <<= 1; texturewidthmask[i] = k - 1; textureheight[i] = texture->height << FRACBITS; } } } } static texpatch_t *R_ParsePatch(boolean actuallyLoadPatch) { char *texturesToken; size_t texturesTokenLength; char *endPos; char *patchName = NULL; INT16 patchXPos; INT16 patchYPos; texpatch_t *resultPatch = NULL; lumpnum_t patchLumpNum; // Patch identifier texturesToken = M_GetToken(NULL); if (texturesToken == NULL) { I_Error("Error parsing TEXTURES lump: Unexpected end of file where patch name should be"); } texturesTokenLength = strlen(texturesToken); if (texturesTokenLength>8) { I_Error("Error parsing TEXTURES lump: Patch name \"%s\" exceeds 8 characters",texturesToken); } else { if (patchName != NULL) { Z_Free(patchName); } patchName = (char *)Z_Malloc((texturesTokenLength+1)*sizeof(char),PU_STATIC,NULL); M_Memcpy(patchName,texturesToken,texturesTokenLength*sizeof(char)); patchName[texturesTokenLength] = '\0'; } // Comma 1 Z_Free(texturesToken); texturesToken = M_GetToken(NULL); if (texturesToken == NULL) { I_Error("Error parsing TEXTURES lump: Unexpected end of file where comma after \"%s\"'s patch name should be",patchName); } if (strcmp(texturesToken,",")!=0) { I_Error("Error parsing TEXTURES lump: Expected \",\" after %s's patch name, got \"%s\"",patchName,texturesToken); } // XPos Z_Free(texturesToken); texturesToken = M_GetToken(NULL); if (texturesToken == NULL) { I_Error("Error parsing TEXTURES lump: Unexpected end of file where patch \"%s\"'s x coordinate should be",patchName); } endPos = NULL; #ifndef AVOID_ERRNO errno = 0; #endif patchXPos = strtol(texturesToken,&endPos,10); (void)patchXPos; //unused for now if (endPos == texturesToken // Empty string || *endPos != '\0' // Not end of string #ifndef AVOID_ERRNO || errno == ERANGE // Number out-of-range #endif ) { I_Error("Error parsing TEXTURES lump: Expected an integer for patch \"%s\"'s x coordinate, got \"%s\"",patchName,texturesToken); } // Comma 2 Z_Free(texturesToken); texturesToken = M_GetToken(NULL); if (texturesToken == NULL) { I_Error("Error parsing TEXTURES lump: Unexpected end of file where comma after patch \"%s\"'s x coordinate should be",patchName); } if (strcmp(texturesToken,",")!=0) { I_Error("Error parsing TEXTURES lump: Expected \",\" after patch \"%s\"'s x coordinate, got \"%s\"",patchName,texturesToken); } // YPos Z_Free(texturesToken); texturesToken = M_GetToken(NULL); if (texturesToken == NULL) { I_Error("Error parsing TEXTURES lump: Unexpected end of file where patch \"%s\"'s y coordinate should be",patchName); } endPos = NULL; #ifndef AVOID_ERRNO errno = 0; #endif patchYPos = strtol(texturesToken,&endPos,10); (void)patchYPos; //unused for now if (endPos == texturesToken // Empty string || *endPos != '\0' // Not end of string #ifndef AVOID_ERRNO || errno == ERANGE // Number out-of-range #endif ) { I_Error("Error parsing TEXTURES lump: Expected an integer for patch \"%s\"'s y coordinate, got \"%s\"",patchName,texturesToken); } Z_Free(texturesToken); if (actuallyLoadPatch == true) { // Check lump exists patchLumpNum = W_GetNumForName(patchName); // If so, allocate memory for texpatch_t and fill 'er up resultPatch = (texpatch_t *)Z_Malloc(sizeof(texpatch_t),PU_STATIC,NULL); resultPatch->originx = patchXPos; resultPatch->originy = patchYPos; resultPatch->lump = patchLumpNum & 65535; resultPatch->wad = patchLumpNum>>16; // Clean up a little after ourselves Z_Free(patchName); // Then return it return resultPatch; } else { Z_Free(patchName); return NULL; } } static texture_t *R_ParseTexture(boolean actuallyLoadTexture) { char *texturesToken; size_t texturesTokenLength; char *endPos; INT32 newTextureWidth; INT32 newTextureHeight; texture_t *resultTexture = NULL; texpatch_t *newPatch; char newTextureName[9]; // no longer dynamically allocated // Texture name texturesToken = M_GetToken(NULL); if (texturesToken == NULL) { I_Error("Error parsing TEXTURES lump: Unexpected end of file where texture name should be"); } texturesTokenLength = strlen(texturesToken); if (texturesTokenLength>8) { I_Error("Error parsing TEXTURES lump: Texture name \"%s\" exceeds 8 characters",texturesToken); } else { memset(&newTextureName, 0, 9); M_Memcpy(newTextureName, texturesToken, texturesTokenLength); // ^^ we've confirmed that the token is <= 8 characters so it will never overflow a 9 byte char buffer strupr(newTextureName); // Just do this now so we don't have to worry about it } Z_Free(texturesToken); // Comma 1 texturesToken = M_GetToken(NULL); if (texturesToken == NULL) { I_Error("Error parsing TEXTURES lump: Unexpected end of file where comma after texture \"%s\"'s name should be",newTextureName); } else if (strcmp(texturesToken,",")!=0) { I_Error("Error parsing TEXTURES lump: Expected \",\" after texture \"%s\"'s name, got \"%s\"",newTextureName,texturesToken); } Z_Free(texturesToken); // Width texturesToken = M_GetToken(NULL); if (texturesToken == NULL) { I_Error("Error parsing TEXTURES lump: Unexpected end of file where texture \"%s\"'s width should be",newTextureName); } endPos = NULL; #ifndef AVOID_ERRNO errno = 0; #endif newTextureWidth = strtol(texturesToken,&endPos,10); if (endPos == texturesToken // Empty string || *endPos != '\0' // Not end of string #ifndef AVOID_ERRNO || errno == ERANGE // Number out-of-range #endif || newTextureWidth < 0) // Number is not positive { I_Error("Error parsing TEXTURES lump: Expected a positive integer for texture \"%s\"'s width, got \"%s\"",newTextureName,texturesToken); } Z_Free(texturesToken); // Comma 2 texturesToken = M_GetToken(NULL); if (texturesToken == NULL) { I_Error("Error parsing TEXTURES lump: Unexpected end of file where comma after texture \"%s\"'s width should be",newTextureName); } if (strcmp(texturesToken,",")!=0) { I_Error("Error parsing TEXTURES lump: Expected \",\" after texture \"%s\"'s width, got \"%s\"",newTextureName,texturesToken); } Z_Free(texturesToken); // Height texturesToken = M_GetToken(NULL); if (texturesToken == NULL) { I_Error("Error parsing TEXTURES lump: Unexpected end of file where texture \"%s\"'s height should be",newTextureName); } endPos = NULL; #ifndef AVOID_ERRNO errno = 0; #endif newTextureHeight = strtol(texturesToken,&endPos,10); if (endPos == texturesToken // Empty string || *endPos != '\0' // Not end of string #ifndef AVOID_ERRNO || errno == ERANGE // Number out-of-range #endif || newTextureHeight < 0) // Number is not positive { I_Error("Error parsing TEXTURES lump: Expected a positive integer for texture \"%s\"'s height, got \"%s\"",newTextureName,texturesToken); } Z_Free(texturesToken); // Left Curly Brace texturesToken = M_GetToken(NULL); if (texturesToken == NULL) { I_Error("Error parsing TEXTURES lump: Unexpected end of file where open curly brace for texture \"%s\" should be",newTextureName); } if (strcmp(texturesToken,"{")==0) { if (actuallyLoadTexture) { // Allocate memory for a zero-patch texture. Obviously, we'll be adding patches momentarily. resultTexture = (texture_t *)Z_Calloc(sizeof(texture_t),PU_STATIC,NULL); M_Memcpy(resultTexture->name, newTextureName, 8); resultTexture->width = newTextureWidth; resultTexture->height = newTextureHeight; } Z_Free(texturesToken); texturesToken = M_GetToken(NULL); if (texturesToken == NULL) { I_Error("Error parsing TEXTURES lump: Unexpected end of file where patch definition for texture \"%s\" should be",newTextureName); } while (strcmp(texturesToken,"}")!=0) { if (stricmp(texturesToken, "PATCH")==0) { Z_Free(texturesToken); if (resultTexture) { // Get that new patch newPatch = R_ParsePatch(true); // Make room for the new patch resultTexture = Z_Realloc(resultTexture, sizeof(texture_t) + (resultTexture->patchcount+1)*sizeof(texpatch_t), PU_STATIC, NULL); // Populate the uninitialized values in the new patch entry of our array M_Memcpy(&resultTexture->patches[resultTexture->patchcount], newPatch, sizeof(texpatch_t)); // Account for the new number of patches in the texture resultTexture->patchcount++; // Then free up the memory assigned to R_ParsePatch, as it's unneeded now Z_Free(newPatch); } else { R_ParsePatch(false); } } else { I_Error("Error parsing TEXTURES lump: Expected \"PATCH\" in texture \"%s\", got \"%s\"",newTextureName,texturesToken); } texturesToken = M_GetToken(NULL); if (texturesToken == NULL) { I_Error("Error parsing TEXTURES lump: Unexpected end of file where patch declaration or right curly brace for texture \"%s\" should be",newTextureName); } } if (resultTexture && resultTexture->patchcount == 0) { I_Error("Error parsing TEXTURES lump: Texture \"%s\" must have at least one patch",newTextureName); } } else { I_Error("Error parsing TEXTURES lump: Expected \"{\" for texture \"%s\", got \"%s\"",newTextureName,texturesToken); } Z_Free(texturesToken); if (actuallyLoadTexture) return resultTexture; else return NULL; } // Parses the TEXTURES lump... but just to count the number of textures. int R_CountTexturesInTEXTURESLump(UINT16 wadNum, UINT16 lumpNum) { char *texturesLump; size_t texturesLumpLength; char *texturesText; UINT32 numTexturesInLump = 0; char *texturesToken; // Since lumps AREN'T \0-terminated like I'd assumed they should be, I'll // need to make a space of memory where I can ensure that it will terminate // correctly. Start by loading the relevant data from the WAD. texturesLump = (char *)W_CacheLumpNumPwad(wadNum, lumpNum, PU_STATIC); // If that didn't exist, we have nothing to do here. if (texturesLump == NULL) return 0; // If we're still here, then it DOES exist; figure out how long it is, and allot memory accordingly. texturesLumpLength = W_LumpLengthPwad(wadNum, lumpNum); texturesText = (char *)Z_Malloc((texturesLumpLength+1)*sizeof(char),PU_STATIC,NULL); // Now move the contents of the lump into this new location. memmove(texturesText,texturesLump,texturesLumpLength); // Make damn well sure the last character in our new memory location is \0. texturesText[texturesLumpLength] = '\0'; // Finally, free up the memory from the first data load, because we really // don't need it. Z_Free(texturesLump); texturesToken = M_GetToken(texturesText); while (texturesToken != NULL) { if (stricmp(texturesToken, "WALLTEXTURE")==0) { numTexturesInLump++; Z_Free(texturesToken); R_ParseTexture(false); } else { I_Error("Error parsing TEXTURES lump: Expected \"WALLTEXTURE\", got \"%s\"",texturesToken); } texturesToken = M_GetToken(NULL); } Z_Free(texturesToken); Z_Free((void *)texturesText); return numTexturesInLump; } // Parses the TEXTURES lump... for real, this time. void R_ParseTEXTURESLump(UINT16 wadNum, UINT16 lumpNum, INT32 *texindex) { char *texturesLump; size_t texturesLumpLength; char *texturesText; char *texturesToken; texture_t *newTexture; I_Assert(texindex != NULL); // Since lumps AREN'T \0-terminated like I'd assumed they should be, I'll // need to make a space of memory where I can ensure that it will terminate // correctly. Start by loading the relevant data from the WAD. texturesLump = (char *)W_CacheLumpNumPwad(wadNum, lumpNum, PU_STATIC); // If that didn't exist, we have nothing to do here. if (texturesLump == NULL) return; // If we're still here, then it DOES exist; figure out how long it is, and allot memory accordingly. texturesLumpLength = W_LumpLengthPwad(wadNum, lumpNum); texturesText = (char *)Z_Malloc((texturesLumpLength+1)*sizeof(char),PU_STATIC,NULL); // Now move the contents of the lump into this new location. memmove(texturesText,texturesLump,texturesLumpLength); // Make damn well sure the last character in our new memory location is \0. texturesText[texturesLumpLength] = '\0'; // Finally, free up the memory from the first data load, because we really // don't need it. Z_Free(texturesLump); texturesToken = M_GetToken(texturesText); while (texturesToken != NULL) { if (stricmp(texturesToken, "WALLTEXTURE")==0) { Z_Free(texturesToken); // Get the new texture newTexture = R_ParseTexture(true); // Store the new texture textures[*texindex] = newTexture; texturewidthmask[*texindex] = newTexture->width - 1; textureheight[*texindex] = newTexture->height << FRACBITS; // Increment i back in R_LoadTextures() (*texindex)++; } else { I_Error("Error parsing TEXTURES lump: Expected \"WALLTEXTURE\", got \"%s\"",texturesToken); } texturesToken = M_GetToken(NULL); } Z_Free(texturesToken); Z_Free((void *)texturesText); } /* static inline lumpnum_t R_CheckNumForNameList(const char *name, lumplist_t *list, size_t listsize) // SRB2kart - unused. { size_t i; UINT16 lump; for (i = listsize - 1; i < INT16_MAX; i--) { lump = W_CheckNumForNamePwad(name, list[i].wadfile, list[i].firstlump); if (lump == INT16_MAX || lump > (list[i].firstlump + list[i].numlumps)) continue; else return (list[i].wadfile<<16)+lump; } return LUMPERROR; } */ /*static lumplist_t *colormaplumps = NULL; ///\todo free leak static size_t numcolormaplumps = 0; static void R_InitExtraColormaps(void) { lumpnum_t startnum, endnum; UINT16 cfile, clump; static size_t maxcolormaplumps = 16; for (cfile = clump = 0; cfile < numwadfiles; cfile++, clump = 0) { startnum = W_CheckNumForNamePwad("C_START", cfile, clump); if (startnum == INT16_MAX) continue; endnum = W_CheckNumForNamePwad("C_END", cfile, clump); if (endnum == INT16_MAX) I_Error("R_InitExtraColormaps: C_START without C_END\n"); // This shouldn't be possible when you use the Pwad function, silly //if (WADFILENUM(startnum) != WADFILENUM(endnum)) //I_Error("R_InitExtraColormaps: C_START and C_END in different wad files!\n"); if (numcolormaplumps >= maxcolormaplumps) maxcolormaplumps *= 2; colormaplumps = Z_Realloc(colormaplumps, sizeof (*colormaplumps) * maxcolormaplumps, PU_STATIC, NULL); colormaplumps[numcolormaplumps].wadfile = cfile; colormaplumps[numcolormaplumps].firstlump = startnum+1; colormaplumps[numcolormaplumps].numlumps = endnum - (startnum + 1); numcolormaplumps++; } CONS_Printf(M_GetText("Number of Extra Colormaps: %s\n"), sizeu1(numcolormaplumps)); }*/ // Search for flat name. lumpnum_t R_GetFlatNumForName(const char *name) { INT32 i; lumpnum_t lump; lumpnum_t start; lumpnum_t end; // Scan wad files backwards so patched flats take preference. for (i = numwadfiles - 1; i >= 0; i--) { switch (wadfiles[i]->type) { case RET_WAD: if ((start = W_CheckNumForNamePwad("F_START", (UINT16)i, 0)) == INT16_MAX) { if ((start = W_CheckNumForNamePwad("FF_START", (UINT16)i, 0)) == INT16_MAX) continue; else if ((end = W_CheckNumForNamePwad("FF_END", (UINT16)i, start)) == INT16_MAX) continue; } else if ((end = W_CheckNumForNamePwad("F_END", (UINT16)i, start)) == INT16_MAX) continue; break; case RET_PK3: if ((start = W_CheckNumForFolderStartPK3("Flats/", i, 0)) == INT16_MAX) continue; if ((end = W_CheckNumForFolderEndPK3("Flats/", i, start)) == INT16_MAX) continue; break; default: continue; } // Now find lump with specified name in that range. lump = W_CheckNumForNamePwad(name, (UINT16)i, start); if (lump < end) { lump += (i<<16); // found it, in our constraints break; } lump = LUMPERROR; } if (lump == LUMPERROR) { if (strcmp(name, SKYFLATNAME)) CONS_Debug(DBG_SETUP, "R_GetFlatNumForName: Could not find flat %.8s\n", name); lump = W_CheckNumForName("REDFLR"); } return lump; } // // R_InitSpriteLumps // Finds the width and hoffset of all sprites in the wad, so the sprite does not need to be // cached completely, just for having the header info ready during rendering. // // // allocate sprite lookup tables // static void R_InitSpriteLumps(void) { numspritelumps = 0; max_spritelumps = 8192; Z_Malloc(max_spritelumps*sizeof(*spritecachedinfo), PU_STATIC, &spritecachedinfo); } // // R_InitColormaps // static void R_InitColormaps(void) { lumpnum_t lump; // Load in the light tables lump = W_GetNumForName("COLORMAP"); //Z_MallocAlign(W_LumpLength (lump), PU_STATIC, NULL, 8); colormaps = Z_MallocAlign((256 * 64), PU_STATIC, NULL, 8); W_ReadLump(lump, colormaps); // no need to init encoremap at this stage // Init Boom colormaps. R_ClearColormaps(); //R_InitExtraColormaps(); #ifdef HASINVERT R_MakeInvertmap(); // this isn't the BEST place to do it the first time, but whatever #endif } void R_ReInitColormaps(UINT16 num, lumpnum_t newencoremap) { char colormap[9] = "COLORMAP"; lumpnum_t lump; if (num > 0 && num <= 10000) snprintf(colormap, 8, "CLM%04u", num-1); // Load in the light tables, now 64k aligned for smokie... lump = W_GetNumForName(colormap); if (lump == LUMPERROR) lump = W_GetNumForName("COLORMAP"); W_ReadLump(lump, colormaps); // Encore mode. if (newencoremap != LUMPERROR) { lighttable_t *colormap_p, *colormap_p2; size_t p, i; encoremap = Z_MallocAlign(256 + 10, PU_LEVEL, NULL, 8); W_ReadLump(newencoremap, encoremap); colormap_p = colormap_p2 = colormaps; colormap_p += (256 * 32); for (p = 0; p < 32; p++) { for (i = 0; i < 256; i++) { *colormap_p = colormap_p2[encoremap[i]]; colormap_p++; } colormap_p2 += 256; } } else encoremap = NULL; // Init Boom colormaps. R_ClearColormaps(); } static lumpnum_t foundcolormaps[MAXCOLORMAPS]; // // R_ClearColormaps // // Clears out extra colormaps between levels. // void R_ClearColormaps(void) { size_t i; num_extra_colormaps = 0; for (i = 0; i < MAXCOLORMAPS; i++) foundcolormaps[i] = LUMPERROR; memset(extra_colormaps, 0, sizeof (extra_colormaps)); } /*INT32 R_ColormapNumForName(char *name) { lumpnum_t lump, i; if (num_extra_colormaps == MAXCOLORMAPS) I_Error("R_ColormapNumForName: Too many colormaps! the limit is %d\n", MAXCOLORMAPS); lump = R_CheckNumForNameList(name, colormaplumps, numcolormaplumps); if (lump == LUMPERROR) I_Error("R_ColormapNumForName: Cannot find colormap lump %.8s\n", name); for (i = 0; i < num_extra_colormaps; i++) if (lump == foundcolormaps[i]) return i; foundcolormaps[num_extra_colormaps] = lump; // aligned on 8 bit for asm code extra_colormaps[num_extra_colormaps].colormap = Z_MallocAlign(W_LumpLength(lump), PU_LEVEL, NULL, 16); W_ReadLump(lump, extra_colormaps[num_extra_colormaps].colormap); // We set all params of the colormap to normal because there // is no real way to tell how GL should handle a colormap lump anyway.. extra_colormaps[num_extra_colormaps].maskcolor = 0xffff; extra_colormaps[num_extra_colormaps].fadecolor = 0x0; extra_colormaps[num_extra_colormaps].maskamt = 0x0; extra_colormaps[num_extra_colormaps].fadestart = 0; extra_colormaps[num_extra_colormaps].fadeend = 31; extra_colormaps[num_extra_colormaps].fog = 0; num_extra_colormaps++; return (INT32)num_extra_colormaps - 1; }*/ // // R_CreateColormap // // This is a more GL friendly way of doing colormaps: Specify colormap // data in a special linedef's texture areas and use that to generate // custom colormaps at runtime. NOTE: For GL mode, we only need to color // data and not the colormap data. // static double deltas[256][3], map[256][3]; static int RoundUp(double number); #ifdef HASINVERT void R_MakeInvertmap(void) { size_t i; for (i = 0; i < 256; i++) invertmap[i] = NearestColor(256 - pLocalPalette[i].s.red, 256 - pLocalPalette[i].s.green, 256 - pLocalPalette[i].s.blue); } #endif INT32 R_CreateColormap(char *p1, char *p2, char *p3) { double cmaskr, cmaskg, cmaskb, cdestr, cdestg, cdestb; double maskamt = 0, othermask = 0; int mask, fog = 0; size_t mapnum = num_extra_colormaps; size_t i; UINT32 cr, cg, cb, maskcolor, fadecolor; UINT32 fadestart = 0, fadeend = 31, fadedist = 31; #define HEX2INT(x) (UINT32)(x >= '0' && x <= '9' ? x - '0' : x >= 'a' && x <= 'f' ? x - 'a' + 10 : x >= 'A' && x <= 'F' ? x - 'A' + 10 : 0) if (p1[0] == '#') { cr = ((HEX2INT(p1[1]) * 16) + HEX2INT(p1[2])); cg = ((HEX2INT(p1[3]) * 16) + HEX2INT(p1[4])); cb = ((HEX2INT(p1[5]) * 16) + HEX2INT(p1[6])); if (encoremap) { i = encoremap[NearestColor((UINT8)cr, (UINT8)cg, (UINT8)cb)]; //CONS_Printf("R_CreateColormap: encoremap[%d] = %d\n", i, encoremap[i]); -- moved encoremap upwards for optimisation cr = pLocalPalette[i].s.red; cg = pLocalPalette[i].s.green; cb = pLocalPalette[i].s.blue; } cmaskr = cr; cmaskg = cg; cmaskb = cb; // Create a rough approximation of the color (a 16 bit color) maskcolor = ((cb) >> 3) + (((cg) >> 2) << 5) + (((cr) >> 3) << 11); if (p1[7] >= 'a' && p1[7] <= 'z') mask = (p1[7] - 'a'); else if (p1[7] >= 'A' && p1[7] <= 'Z') mask = (p1[7] - 'A'); else mask = 24; maskamt = (double)(mask/24.0l); othermask = 1 - maskamt; maskamt /= 0xff; cmaskr *= maskamt; cmaskg *= maskamt; cmaskb *= maskamt; } else { cmaskr = cmaskg = cmaskb = 0xff; maskamt = 0; maskcolor = ((0xff) >> 3) + (((0xff) >> 2) << 5) + (((0xff) >> 3) << 11); } #define NUMFROMCHAR(c) (c >= '0' && c <= '9' ? c - '0' : 0) if (p2[0] == '#') { // Get parameters like fadestart, fadeend, and the fogflag fadestart = NUMFROMCHAR(p2[3]) + (NUMFROMCHAR(p2[2]) * 10); fadeend = NUMFROMCHAR(p2[5]) + (NUMFROMCHAR(p2[4]) * 10); if (fadestart > 30) fadestart = 0; if (fadeend > 31 || fadeend < 1) fadeend = 31; fadedist = fadeend - fadestart; fog = NUMFROMCHAR(p2[1]); } #undef NUMFROMCHAR if (p3[0] == '#') { cr = ((HEX2INT(p3[1]) * 16) + HEX2INT(p3[2])); cg = ((HEX2INT(p3[3]) * 16) + HEX2INT(p3[4])); cb = ((HEX2INT(p3[5]) * 16) + HEX2INT(p3[6])); if (encoremap) { i = encoremap[NearestColor((UINT8)cr, (UINT8)cg, (UINT8)cb)]; cr = pLocalPalette[i].s.red; cg = pLocalPalette[i].s.green; cb = pLocalPalette[i].s.blue; } cdestr = cr; cdestg = cg; cdestb = cb; fadecolor = (((cb) >> 3) + (((cg) >> 2) << 5) + (((cr) >> 3) << 11)); } else cdestr = cdestg = cdestb = fadecolor = 0; #undef HEX2INT for (i = 0; i < num_extra_colormaps; i++) { if (foundcolormaps[i] != LUMPERROR) continue; if (maskcolor == extra_colormaps[i].maskcolor && fadecolor == extra_colormaps[i].fadecolor && fabs(maskamt - extra_colormaps[i].maskamt) < DBL_EPSILON && fadestart == extra_colormaps[i].fadestart && fadeend == extra_colormaps[i].fadeend && fog == extra_colormaps[i].fog) { return (INT32)i; } } if (num_extra_colormaps == MAXCOLORMAPS) I_Error("R_CreateColormap: Too many colormaps! the limit is %d\n", MAXCOLORMAPS); num_extra_colormaps++; foundcolormaps[mapnum] = LUMPERROR; // aligned on 8 bit for asm code extra_colormaps[mapnum].colormap = NULL; extra_colormaps[mapnum].maskcolor = (UINT16)maskcolor; extra_colormaps[mapnum].fadecolor = (UINT16)fadecolor; extra_colormaps[mapnum].maskamt = maskamt; extra_colormaps[mapnum].fadestart = (UINT16)fadestart; extra_colormaps[mapnum].fadeend = (UINT16)fadeend; extra_colormaps[mapnum].fog = fog; if (rendermode == render_soft) { double r, g, b, cbrightness; int p; lighttable_t *colormap_p; // Initialise the map and delta arrays // map[i] stores an RGB color (as double) for index i, // which is then converted to SRB2's palette later // deltas[i] stores a corresponding fade delta between the RGB color and the final fade color; // map[i]'s values are decremented by after each use for (i = 0; i < 256; i++) { r = pLocalPalette[i].s.red; g = pLocalPalette[i].s.green; b = pLocalPalette[i].s.blue; cbrightness = sqrt((r*r) + (g*g) + (b*b)); map[i][0] = (cbrightness * cmaskr) + (r * othermask); if (map[i][0] > 255.0l) map[i][0] = 255.0l; deltas[i][0] = (map[i][0] - cdestr) / (double)fadedist; map[i][1] = (cbrightness * cmaskg) + (g * othermask); if (map[i][1] > 255.0l) map[i][1] = 255.0l; deltas[i][1] = (map[i][1] - cdestg) / (double)fadedist; map[i][2] = (cbrightness * cmaskb) + (b * othermask); if (map[i][2] > 255.0l) map[i][2] = 255.0l; deltas[i][2] = (map[i][2] - cdestb) / (double)fadedist; } // Now allocate memory for the actual colormap array itself! colormap_p = Z_MallocAlign((256 * (encoremap ? 64 : 32)) + 10, PU_LEVEL, NULL, 8); extra_colormaps[mapnum].colormap = (UINT8 *)colormap_p; // Calculate the palette index for each palette index, for each light level // (as well as the two unused colormap lines we inherited from Doom) for (p = 0; p < 32; p++) { for (i = 0; i < 256; i++) { *colormap_p = NearestColor((UINT8)RoundUp(map[i][0]), (UINT8)RoundUp(map[i][1]), (UINT8)RoundUp(map[i][2])); colormap_p++; if ((UINT32)p < fadestart) continue; #define ABS2(x) ((x) < 0 ? -(x) : (x)) if (ABS2(map[i][0] - cdestr) > ABS2(deltas[i][0])) map[i][0] -= deltas[i][0]; else map[i][0] = cdestr; if (ABS2(map[i][1] - cdestg) > ABS2(deltas[i][1])) map[i][1] -= deltas[i][1]; else map[i][1] = cdestg; if (ABS2(map[i][2] - cdestb) > ABS2(deltas[i][1])) map[i][2] -= deltas[i][2]; else map[i][2] = cdestb; #undef ABS2 } } if (encoremap) { lighttable_t *colormap_p2 = extra_colormaps[mapnum].colormap; for (p = 0; p < 32; p++) { for (i = 0; i < 256; i++) { *colormap_p = colormap_p2[encoremap[i]]; colormap_p++; } colormap_p2 += 256; } } } return (INT32)mapnum; } // Thanks to quake2 source! // utils3/qdata/images.c UINT8 NearestColor(UINT8 r, UINT8 g, UINT8 b) { int dr, dg, db; int distortion, bestdistortion = 256 * 256 * 4, bestcolor = 0, i; for (i = 0; i < 256; i++) { dr = r - pLocalPalette[i].s.red; dg = g - pLocalPalette[i].s.green; db = b - pLocalPalette[i].s.blue; distortion = dr*dr + dg*dg + db*db; if (distortion < bestdistortion) { if (!distortion) return (UINT8)i; bestdistortion = distortion; bestcolor = i; } } return (UINT8)bestcolor; } // Rounds off floating numbers and checks for 0 - 255 bounds static int RoundUp(double number) { if (number > 255.0l) return 255; if (number < 0.0l) return 0; if ((int)number <= (int)(number - 0.5f)) return (int)number + 1; return (int)number; } const char *R_ColormapNameForNum(INT32 num) { if (num == -1) return "NONE"; if (num < 0 || num > MAXCOLORMAPS) I_Error("R_ColormapNameForNum: num %d is invalid!\n", num); if (foundcolormaps[num] == LUMPERROR) return "INLEVEL"; return W_CheckNameForNum(foundcolormaps[num]); } // // build a table for quick conversion from 8bpp to 15bpp // // // added "static inline" keywords, linking with the debug version // of allegro, it have a makecol15 function of it's own, now // with "static inline" keywords,it sloves this problem ;) // FUNCMATH static inline int makecol15(int r, int g, int b) { return (((r >> 3) << 10) | ((g >> 3) << 5) | ((b >> 3))); } static void R_Init8to16(void) { UINT8 *palette; int i; palette = W_CacheLumpName("PLAYPAL",PU_CACHE); for (i = 0; i < 256; i++) { // PLAYPAL uses 8 bit values color8to16[i] = (INT16)makecol15(palette[0], palette[1], palette[2]); palette += 3; } // test a big colormap hicolormaps = Z_Malloc(16384*sizeof(*hicolormaps), PU_STATIC, NULL); for (i = 0; i < 16384; i++) hicolormaps[i] = (INT16)(i<<1); } // // R_InitData // // Locates all the lumps that will be used by all views // Must be called after W_Init. // void R_InitData(void) { if (highcolor) { CONS_Printf("InitHighColor...\n"); R_Init8to16(); } CONS_Printf("R_LoadTextures()...\n"); R_LoadTextures(); CONS_Printf("P_InitPicAnims()...\n"); P_InitPicAnims(); CONS_Printf("R_InitSprites()...\n"); R_InitSpriteLumps(); R_InitSprites(); CONS_Printf("R_InitColormaps()...\n"); R_InitColormaps(); } void R_ClearTextureNumCache(boolean btell) { if (tidcache) Z_Free(tidcache); tidcache = NULL; if (btell) CONS_Debug(DBG_SETUP, "Fun Fact: There are %d textures used in this map.\n", tidcachelen); tidcachelen = 0; } // // R_CheckTextureNumForName // // Check whether texture is available. Filter out NoTexture indicator. // INT32 R_CheckTextureNumForName(const char *name) { INT32 i; // "NoTexture" marker. if (name[0] == '-') return 0; for (i = 0; i < tidcachelen; i++) if (!strncasecmp(tidcache[i].name, name, 8)) return tidcache[i].id; // Need to parse the list backwards, so textures loaded more recently are used in lieu of ones loaded earlier //for (i = 0; i < numtextures; i++) <- old for (i = (numtextures - 1); i >= 0; i--) // <- new if (!strncasecmp(textures[i]->name, name, 8)) { tidcachelen++; Z_Realloc(tidcache, tidcachelen * sizeof(*tidcache), PU_STATIC, &tidcache); strncpy(tidcache[tidcachelen-1].name, name, 8); tidcache[tidcachelen-1].name[8] = '\0'; #ifndef ZDEBUG CONS_Debug(DBG_SETUP, "texture #%s: %s\n", sizeu1(tidcachelen), tidcache[tidcachelen-1].name); #endif tidcache[tidcachelen-1].id = i; return i; } return -1; } // // R_TextureNumForName // // Calls R_CheckTextureNumForName, aborts with error message. // INT32 R_TextureNumForName(const char *name) { const INT32 i = R_CheckTextureNumForName(name); if (i == -1) { static INT32 redwall = -2; CONS_Debug(DBG_SETUP, "WARNING: R_TextureNumForName: %.8s not found\n", name); if (redwall == -2) redwall = R_CheckTextureNumForName("REDWALL"); if (redwall != -1) return redwall; return 1; } return i; } // // R_PrecacheLevel // // Preloads all relevant graphics for the level. // void R_PrecacheLevel(void) { char *texturepresent, *spritepresent; size_t i, j, k; lumpnum_t lump; thinker_t *th; spriteframe_t *sf; if (demo.playback) return; // do not flush the memory, Z_Malloc twice with same user will cause error in Z_CheckHeap() if (rendermode != render_soft) return; // Precache flats. flatmemory = P_PrecacheLevelFlats(); // // Precache textures. // // no need to precache all software textures in 3D mode // (note they are still used with the reference software view) texturepresent = calloc(numtextures, sizeof (*texturepresent)); if (texturepresent == NULL) I_Error("%s: Out of memory looking up textures", "R_PrecacheLevel"); for (j = 0; j < numsides; j++) { // huh, a potential bug here???? if (sides[j].toptexture >= 0 && sides[j].toptexture < numtextures) texturepresent[sides[j].toptexture] = 1; if (sides[j].midtexture >= 0 && sides[j].midtexture < numtextures) texturepresent[sides[j].midtexture] = 1; if (sides[j].bottomtexture >= 0 && sides[j].bottomtexture < numtextures) texturepresent[sides[j].bottomtexture] = 1; } // Sky texture is always present. // Note that F_SKY1 is the name used to indicate a sky floor/ceiling as a flat, // while the sky texture is stored like a wall texture, with a skynum dependent name. texturepresent[skytexture] = 1; texturememory = 0; for (j = 0; j < (unsigned)numtextures; j++) { if (!texturepresent[j]) continue; if (!texturecache[j]) R_GenerateTexture(j); // pre-caching individual patches that compose textures became obsolete, // since we cache entire composite textures } free(texturepresent); // // Precache sprites. // spritepresent = calloc(numsprites, sizeof (*spritepresent)); if (spritepresent == NULL) I_Error("%s: Out of memory looking up sprites", "R_PrecacheLevel"); for (th = thinkercap.next; th != &thinkercap; th = th->next) if (th->function.acp1 == (actionf_p1)P_MobjThinker) spritepresent[((mobj_t *)th)->sprite] = 1; spritememory = 0; for (i = 0; i < numsprites; i++) { if (!spritepresent[i]) continue; for (j = 0; j < sprites[i].numframes; j++) { sf = &sprites[i].spriteframes[j]; for (k = 0; k < 8; k++) { // see R_InitSprites for more about lumppat,lumpid lump = sf->lumppat[k]; if (devparm) spritememory += W_LumpLength(lump); W_CachePatchNum(lump, PU_CACHE); } } } free(spritepresent); // FIXME: this is no longer correct with OpenGL render mode CONS_Debug(DBG_SETUP, "Precache level done:\n" "flatmemory: %s k\n" "texturememory: %s k\n" "spritememory: %s k\n", sizeu1(flatmemory>>10), sizeu2(texturememory>>10), sizeu3(spritememory>>10)); }